Compositions and methods for viral resistance genes

ABSTRACT

The present invention further provides a method of evaluating yellow fever virus susceptibility in a subject, which comprises obtaining a nucleic acid containing at least a portion of OAS gene from the subject, and determining whether the nucleic acid comprises SNPs relating to the susceptibility of the subject to yellow fever virus-associated condition. Also provided is a method of evaluating tick-borne encephalitis virus susceptibility in a subject, which comprises obtaining a nucleic acid containing at least a portion of OAS gene from the subject, and whether the nucleic acid comprises SNPs relating to the susceptibility of the subject to tick-borne encephalitis virus-associated condition.

RELATED APPLICATIONS

This application is a continuation-in-part of U.S. patent application Ser. No. 11/012,762, filed Dec. 15, 2004, which is a continuation-in-part of PCT/US2003/19300, filed Jun. 19, 2003, which claimed priority to U.S. Provisional Patent Application No. 60/390,046, filed Jun. 19, 2002, each of which is herein incorporated in its entirety. This application also claims the benefit of U.S. Provisional Patent Application No. 60/796,111, filed Apr. 28, 2006, which is herein incorporated in its entirety.

STATEMENT OF GOVERNMENT INTEREST

This invention was made with government support under Public Health Service Grants: GM54896 from the National Institute of General Medical Sciences and AI45135 from the Institute of Allergy and Infection Diseases, National Institutes of Health. As such, the United States government has certain rights in this invention.

TECHNICAL FIELD

This invention is directed to compositions and methods for viral resistance genes. In particular, the invention is directed to compositions and methods for identifying viral resistance genes and for identifying individuals having the resistance genes.

BACKGROUND OF THE INVENTION

Viruses cause some of the most debilitating illnesses known in animals, including humans, and plants; Vaccination procedures have provided relief from some of the more deadly viruses, such as smallpox, measles, influenza and poliovirus. However, many viruses still cause much human and animal suffering, loss of work days, and sometimes death.

Not all individuals infected with a virus respond identically to the virus. Such individual variation in response to viral pathogens has been seen in both animals and humans. For example, when Australian rabbit populations were controlled by the introduction of a viral pathogen, 99% of the rabbits were killed, but 1% survived. In humans who were accidentally inoculated with hepatitis B virus, only a small percentage developed clinical hepatitis and only a small percentage of those individuals developed severe disease.

Such variation in response to infection, in the extent of the disease state and the ultimate outcome is presumed to be due to multiple factors. Some of these factors include genetic makeup, nutritional status, age, and immune competency. For particular viral pathogens, some of the factors have been suggested as being important, but there are no tests or assays that would enable one to predict an individual's response to exposure to the pathogen.

What is needed are compositions and methods for determining, prior to exposure to the viral pathogen how ill the individual will become if infected. Additionally, such methods could be used for determining which individuals should be vaccinated.

SUMMARY OF THE INVENTION

The present invention comprises compositions and methods for identifying viral resistance/susceptibility genes and for identifying individuals having such viral resistance/susceptibility genes. In particular, compositions and methods for identifying flavivirus resistance/susceptibility genes are provided. Additionally, methods for testing body samples to determine the presence or absence of genes associated with viral resistance/susceptibility are provided.

Inbred mouse strains exhibit significant differences in their susceptibility to viruses in the genus Flavivirus, which includes human pathogens such as yellow fever, Dengue, and West Nile virus. A single gene, designated Flv, confers this differential susceptibility and maps to a region of mouse chromosome 5. A positional cloning strategy was used to identify twenty-two genes from the Flv interval including ten members of the 2′-5′ oligoadenylate synthetase gene family. One 2′-5′ oligoadenylate synthetase gene, Oas1b, was identified as Flv by correlation between genotype and phenotype in nine mouse strains. Susceptible mouse strains produce a protein lacking 30% of the C-terminal sequence as compared to the resistant counterpart due to the presence of a premature stop-codon. The Oas 1b gene differs from all of the other murine Oas genes by a unique four amino acid deletion in the P-loop located within a conserved domain thought to be involved in RNA binding. Expression of the resistant allele of Oas1b in susceptible embryofibroblasts resulted in partial inhibition of the replication of a flavivirus, but not of an alpha togavirus.

There are three types of Oas genes in mammals. The large three unit-containing Oas 3 gene, the two unit-containing Oas 2 gene and the single unit Oas 1 gene. Many mammals also contain single-unit Oas-like genes. The single unit Oas 1 genes have duplicated in mice; there are 8 mouse Oas1 genes. Only one of these, Oas1b, confers flavivirus resistance/susceptibility. In the human genome there is only a single OAS1 gene, but this gene produces multiple isoforms.

The present invention comprises the finding that resistance to infection by flaviviruses has been associated with variations in human OAS genes, particularly OAS1. If an G (G-allele) is present at nt position 12,349 (numbered beginning from the Atg-start codon in the genomic DNA), the p46 and p48 isoforms are produced. If a G to A transversion (A-allele) at nt position 12,349 is present, the p40, p48 and p52 isoforms are produced. The 346 N-terminal amino acids of these four proteins are identical but their C-terminal regions differ due to alternative splicing.

Data showed that the frequency of the A-allele in ethnic Russian populations who are known to be highly resistant to disease caused by the flavivirus, tick borne encephalitis virus, was significantly increased (up to 99%) as compared with the frequency in a group of patients with tick borne encephalitis virus-induced disease (59%). The GG homozygous individuals exhibited the most severe disease symptoms. No GG-homologous individuals were detected in the native Siberian populations. In contrast, the frequencies of the A-allele and the G-allele were similar in groups of healthy Russians and Russians infected with hepatitis C virus (a distantly related member of the flavivirus family from a different genus). Mutations in the human Oas2 and or Oas3 genes may also be relevant to virus resistance/susceptibility.

Methods for determining the individual genotypes have been developed. To determine the presence of the A and G alleles, samples of genetic material from individuals are obtained and the DNA is characterized for the presence or absence of the susceptibility/resistance polymorphism.

The present invention further provides a method of evaluating yellow fever virus susceptibility in a subject, comprising obtaining a nucleic acid from the subject, wherein the nucleic acid comprises at least a portion of OAS gene, or a transcription product thereof; and analyzing at least a portion of the nucleic acid, wherein the existence of at least one SNP selected from the group consisting of rs3741981, rs10774671, rs2660, rs11352835, rs15895, and transcription products thereof in the nucleic acid indicates the susceptibility of the subject to yellow fever virus-associated condition.

Also provided is a method of evaluating tick-borne encephalitis virus susceptibility in a subject, comprising obtaining a nucleic acid from the subject, wherein the nucleic acid comprises at least a portion of OAS gene, or a transcription product thereof; and analyzing at. least a portion of the nucleic acid, wherein the existence of at least one SNP selected from the group consisting of rs1293762, rs2240193, rs2072136, rs1732778, rs12819210, and transcription products thereof in the nucleic acid indicates the susceptibility of the subject to tick-borne encephalitis virus-associated condition.

Other features and advantages of the present invention will become apparent from the following detailed description. It should be understood, however, that the detailed description and the specific examples, while indicating the preferred embodiments of the present invention, are given by way of illustration only, since various changes and modifications within the spirit and scope of the present invention will become apparent to those skilled in the art from this detailed description.

BRIEF DESCRIPTION OF FIGURES

FIG. 1 shows the physical and transcript maps of the mouse Flv interval.

FIGS. 2A and B show the structures of the mouse Oas 1b gene and protein. FIG. 3 is a Northern blot showing the constitutive expression of mouse Oas1b in different mouse tissues.

FIG. 4A is a graph and FIG. 4B is a table showing the effect of low level expression of the resistant Oas1b protein in susceptible C3H/He cells on the growth of a flavivirus, West Nile virus, and an alpha togavirus, Sindbis.

FIG. 5 is an un-rooted neighbor joining, distance-based phylogenic tree of murine, rat and human Oas sequences.

FIG. 6A-H show multiple alignments of the protein sequences of the murine, rat and human 2′-5′ oligoadenylate synthetases.

FIG. 7 shows the relationship of the human OAS gene family members and the murine Oas gene family members. A comparison of the orthologous 2′-5′ oligoadenylate synthetase genes located on Homo sapiens autosome 12 (HSA12,) and Mus musculus autosome 5 (MMA5) are shown. There are eight murine Oas 1 genes (from “a” through “h”) orthologous to a single human OAS1 gene.

FIG. 8 shows the position of a G to A transversion [indicated by r and located at nucleotide position 12,349 (numbered beginning from the ATG-start codon)] in human OAS1 genomic DNA and the amino acids present at the beginning and end of the C-terminal parts of the OAS1 isoforms, p40, p46, p52 and p48, that are generated depending on whether a G or A is present at nucleotide position 12,349.

FIG. 9 is a photograph of ethidium bromide stained PCR DNAs electrophoresed on a 2% agarose gel. The fragment patterns detected for humans with the different : genotypes that determine viral resistance/susceptibility are shown. Lane 1—100 bp DNA ladder; Lane 2—AA homozygous DNA digested with Alu I; Lane 3—AG heterozygous DNA digested with Alu I; Lane 4—GG homozygous DNA digested with Alu I; Lane 5—undigested PCR product.

DETAILED DESCRIPTION

As used herein and in the appended claims, the singular forms “a,” “an,” and “the” include plural references, unless the content clearly dictates otherwise. Thus, for example, reference to “a nucleic acid” includes a plurality of such nucleic acids and equivalents thereof known to those skilled in the art, and reference to “the virus” is a reference to one or more such viruses and equivalents thereof known to those skilled in the art, and so forth. All publications, patent applications, patents, and other references mentioned herein are incorporated by reference in their entirety.

The present invention is directed to compositions and methods for determining gene variations that confer resistance/susceptibility to viral pathogens and for determining the presence or absence of such genes in the genotypes of individuals. The determination of the viral resistance genotype of an individual is important in assessing the individual's response to a known viral pathogen, assessing the population's response to a viral pathogen and may be important in predicting the response of both the individual and the population's response to viral pathogens that enter the environment at a later time.

Global connections and travel are some of the causes of entry of viral pathogens into new geographic areas. For example, mobile populations and growing food imports make it more likely that diseases will continue to spread well beyond the borders where the diseases originated. For example, in the U.S., West Nile virus first appeared in New York in 1999 and has spread southward, northward and westward. Thousands of people have been infected. About 10% of these have developed moderate to severe clinical symptoms and several hundreds of people have died. Countless birds, horses and other animals have been infected and many have died. The virus is predicted to spread throughout the continental United States and to all regions of the Americas.

West Nile virus belongs to a family of disease-causing viruses known as flaviviruses, which are spread by insects, usually mosquitoes but also by ticks. The currently identified flaviviruses include, but are not limited to, tick-borne virus such as mammalian tick-borne virus groups including Gadgets Gully virus, Kadam virus, Kyasanur Forest disease virus, Langat virus, Omsk hemorrhagic fever virus, Powassan virus, Royal Farm virus, Karshi virus, tick-borne encephalitis virus, subtypes European, Far Eastern, and Siberian, Louping ill virus, subtypes, Irish, British, Spanish, and Turkish, Seabird tick-borne virus group including Meaban virus, Saiimarez Reef virus, Tyuleniy virus and also include mosquito-borne viruses such as the Aroa virus group including Aroa virus, Bussuquara virus, Iguape virus, Naranjal virus, the Dengue virus group including Dengue virus, Dengue virus type 1, Dengue virus type 2, Dengue virus type 3, Dengue virus type 4, Kedougou virus, and the Japanese encephalitis virus group including Cacipacore virus, Koutango virus, Japanese encephalitis virus, Alfuy virus, St. Louis encephalitis virus, Usutu virus, West Nile virus, Kunjin virus, Yaounde virus, the Kokobera virus group including Kokobera virus, Stratford virus, the Ntaya virus group including Bagaza virus, Ilheus virus, Rocio virus, Israel turkey meningoencephalomyelitis virus, Ntaya virus, Tembusu virus, the Spondweni virus group including Zika virus, Spondweni virus, the Yellow fever virus group including Banzi virus, Bouboui virus, Edge Hill virus, Jugra virus, Saboya virus, Potiskum virus, Sepik virus, Uganda S virus, Wesselsbron virus, Yellow fever virus and also include viruses with no known arthropod vector such as the Entebbe bat virus group including Entebbe bat virus, Sokoluk virus, Yokose virus, the Mbdoc virus group including Apoi virus, Cowbone Ridge Virus, Jutiapa virus, Modoc virus, Sal Vieja virus, San Perlita virus, the Rio Bravo virus group including Bukalasa bat virus, Carey Island virus, Dakar bat virus, Montana myotis leukoencephalitis virus, Phnom Penh bat virus, Batu Cave virus and Rio Bravo virus. Viruses that may also be included in this group include Tamana bat virus and cell fusing agent virus.

Flaviviruses that are important human pathogens include yellow fever virus, Japanese encephalitis virus, dengue virus, tick borne encephalitis virus and Saint Louis encephalitis virus. Most human infections are asymptomatic or mild, causing fever, headache and body aches, often accompanied by a skin rash and swollen lymph glands. If the virus crosses the blood-brain barrier, life-threatening encephalitis or meningitis is often the result. Polio-like paralysis and Parkinson's disease-like symptoms can also result from. West Nile virus infection. West Nile is most often transmitted by insect vectors, although transmission can also occur through transfusion, transplantation and from mother to child during birth or during breast feeding.

West Nile virus primarily cycles between mosquitoes and birds. Other animals, such as humans or horses, are incidental hosts to which the virus is transmitted during the mosquito's blood meal. Many bird species are infected with West Nile virus, with crows, bluejays and sparrows being some of the most susceptible species. An increase in dead birds is often the first clue that West Nile is invading an area or that the virus is found there is large numbers.

Currently, there are no drugs to treat West Nile virus and no vaccines are available to prevent infection. This lack of treatment and vaccines is the case for many flaviviruses and other viral pathogens. While vaccines are often a goal for medical treatment, vaccines are not without some risk to the individuals being vaccinated. With the compositions and methods of the present invention, the genotypes of individuals in an infected area can be easily determined and this information used to decide what medical intervention may be necessary. If the population is comprised primarily of individuals who are resistant to infection, mass vaccination would be a waste of resources. Additionally, there may be a subset of the population that is highly susceptible and vaccination may cause harm in these individuals. Further, these highly susceptible individuals could take preventive measures, such as reducing exposure to conditions where insects are feeding, and thus avoid illness.

The methods and compositions of the present invention are useful for identifying individuals who are at risk of developing disease, and also for identifying individuals who are resistant to disease. Such individuals comprise mice, and also other species, including, but not limited to humans, horses, cattle, sheep, pigs, wild birds and chickens. It is very expensive to vaccinate farm animals yearly and if the genotypes of the animals are known, only the susceptible animals need be vaccinated. Wild bird populations could be restocked with resistant individuals.

Innate resistance to flavivirus-induced morbidity and mortality was first demonstrated in mice in the 1920's (1) and showed monogenic autosomal dominant inheritance (2). The alleles that determined resistance and susceptibility were designated Flv^(r) and Flv^(s), respectively (3). Resistant mice are susceptible to infections with other types of viruses, but are resistant to all flaviviruses (4). The disease resistance conferred by the Flv^(r) allele has been demonstrated with a number of different flaviviruses. Mosquito-borne flaviruses tested include West Nile virus, dengue, St Louis encephalitis, yellow fever virus, Japanese encephalitis, Banzi, Ilheus, Murray Valley encephalitis, Kunjin, Alfuy and Kokobera. The tick-borne flaviviruses tested include louping ill and Russian Spring Summer encephalitis viruses. Flavivirus resistant and susceptible mouse strains were shown to be equally susceptible to viruses from other families, such as an arenavirus, three bunyaviruses, a picornavirus, two rhabdoviruses, seven alpha togaviruses, and two herpes viruses.

Resistant mice can be infected by flaviviruses, but the virus titers in their tissues are lower by 1,000- to 10,000-times than those in the tissues of susceptible animals and the spread of the infection in resistant mice is slower (5-6). Cell cultures derived from many different tissues of resistant mice also produce lower yields of virus; peak titers from resistant cultures are 100- to 1,000-times lower than from susceptible cultures (7-9). Previous studies indicate that the Flv gene product acts intracellularly on flavivirus replication.

The flavivirus resistant allele was demonstrated in wild Mus musculus domesticus populations in both the U.S. and Australia and flavivirus genetic resistance was also reported in other Mus species (11-13). Most commonly used inbred laboratory mouse strains were derived from a small number of progenitors and the majority of them have a homozygous flavivirus susceptible genotype. Only the Det, BSVR, BRVR, CASA/Rk, CAST/Ei, MOLD/Rk and PRI inbred strains have the resistant allele (10). The characteristics of a resistant-like allele (designated Flv^(r)-like) in CASA/Rk and CAST/Ei strains were similar to those of the PRI Flv^(r) allele. The MOLD/Rk animals carry an allele designated minor resistance Flv^(mr), which can protect carriers from disease after infection with the attenuated 17D strain of yellow fever virus, but not from the virulent Murray Valley encephalitis virus (11).

The resistant allele from donor PRI mice was introduced onto the susceptible C3H/He background to produce the congenic inbred C3H.PRI-Flv^(r) (formerly C3H.RV) strain by a standard backcross protocol followed by brother-sister matings with selection at each generation for the resistance phenotype (13). These congenic strains also carry different alleles of the Ric gene, which controls susceptibility to Rickettsia tsutsugamushi and is located on mouse chromosome 5 (14). These data suggested linkage between the Flv and the Ric loci and the congenic strains were subsequently used to map the Flv locus on mouse chromosome 5 by linkage with the Ric and rd loci (15). Subsequently, twelve microsatellite markers from mouse chromosome 5 were genotyped relative to the Flv gene in 1325 backcross animals. Two of the microsatellite markers, D5Mit408, and D5Mit242, exhibited map distances with the Flv locus of 0.30 and 0.15 centiMorgans (cM), respectively, while one additional marker, D5Mit159, showed no recombination with Flv, indicating linkage of <0.15 cM (16).

To isolate the Flv gene a positional cloning strategy was used. The loci located near the D5Mit159 marker were first identified and then their sequences were compared in cells from congenic resistant and susceptible mice. The Flv gene was identified as mouse 2′-5′ oligoadenylate synthetase 1B (Oas1b) by these methods.

Abbreviations used herein include BAC, bacterial artificial chromosome: Flv, flavivirus resistance gene; Oas, 2′-5′ oligoadenylate synthetase; ORF, open reading frame; WNV, West Nile virus Data depositions, and sequences disclosed herein by specific incorporation, include mouse sequences, AF217002 (SEQ ID 1), AF217003 (SEQ ID 2), AF261233 (SEQ ID 3), AF319547 (SEQ ID 4), AF328926 (SEQ ID 5), AF328927 (SEQ ID 6), AF418004 (SEQ ID 7), AF418005 (SEQ ID 8), AF418006 (SEQ ID 9), AF4188007 (SEQ ID 10), AF88008 (SEQ ID 11), AF418009 (SEQ ID 12), AF418010 (SEQ ID 13), AF453830 (SEQ ID 14), AF459815 (SEQ ID 15), AF459816 (SEQ ID 16), AF478457 (SEQ ID 17), AF480417 (SEQ ID 18), AF481733 (SEQ ID 19), AF481734 (SEQ ID 20), AY055829 (SEQ ID 21), AY055830 (SEQ ID 22), AY055831 (SEQ ID 23), AY057107 (SEQ ID 24), AY196696 (SEQ ID 25), AY196697 (SEQ ID 26), AY196698 (SEQ ID 27), AY196699 (SEQ ID 28), AY196700 (SEQ ID 29), AY221507, (SEQ ID 30), AY196701 (SEQ ID 31), AY227756 (SEQ ID 32), AY230746 (SEQ ID 34), AY237116 (SEQ ID 33), bovine sequence AY243505 (SEQ ID 36), AY250706 (SEQ ID 35), equine sequence AY321355 (SEQ ID 37)

Human genomic OASI sequence (SEQ ID 38) (derived from the GenBank sequence AC00455 (Homo sapiens 12q24.1 PAC RPCI1-71H24), positions 120325-133280, presented here as the reverse complement of the GenBank sequence): aaccaacagcagtccaagctcagtcagcagaagagataaaagcaaacaggtctgggaggcagttctgttgccactctctctcctgtca atgatggatctcagaaataccccagccaaatctctggacaagttcattgaagactatctcttgccagacacgtgtttccgcatgcaaatca accatgccattgacatcatctgtgggttcctgaaggaaaggtgcttccgaggtagctcctaccctgtgtgtgtgtccaaggtggtaaagg tgagtccaggcctgcctggccaggggaggggtggctgaatgtgcaagagttgagattgagaatgagagagagagagagagagaa gcaaaaacctagaacccagggtgcaaatgtgagtacagagagctgagatcttctgggatggtggtttcttatttatccacacagcatgtt aaaatagattctggggtgaaatcctacatccctattattaacaagtgaccctcccccctacttcccgctgaagtttatgaaccactgtcctg ggcgatgcccatttcagaaatagggaactgaatcccagctctggtaaacagtttgctaattcgtggccaggctaggggctcaccatttct gcagtgaagaatcatatgttttgaaagcaaatagcacctgctggctgcaagaccttgagcaagtcacttaactactctgtgttccaatttcc tcagccataatccccaatactgttgcagtcttgccagtgcaccttaatgtagcagcttctcactgaattagtacccaaggttctttgtcctgc atccaagaaaattaaggaacatggacacaaacgtgagcttggagcaaaagttcagtaagcaaaagaagaaagctgtctccactgtgg agagggaagtctgagtggattgccagattgcagctgaatgcaaaaaacttttataagaaaccactctcctccctgtaactgtttgagaaa ctttttatcagtaaagctgtgcaacttcccttaccttatgcagctgtgggtatatctctaggcaagcataaagcgctgcttctcttgtatgtata actgtggatttgttttaggtaagtcccactccctgcgccagtttcaggcaggccgctcctccagggcccagccttgaccatttacctaact gatttttcctctactttccctcaatacctcatagggccgtgtagattaagtaaaatagtaagtgtgaaccacccagcataagctagtcctgg gcatcgtaaaggacaatgggaaaagaacacagatcctggaagaaggcccccaggtttgaattgtatttgccacctactagctgggtga tggggctgatatattatctcactgagcatccattttcccatctgtaaaatgggaactaatgataatggcatccaaatcatagcatcattgtga gcattataggagtttaagacatgcaatgccttcagaacagtggctagtgctccataatgttagtgattgctcctgtcattttatttagggagg tttgcctcactaagcatcaattattattttgtcgtctttttcagggtggctcctcaggcaagggcaccaccctcagaggccgatctgacgct gacctggttgtcttcctcagtcctctcaccacttttcaggatcagttaaatcgccggggagagttcatccaggaaattaggagacagctg gaagcctgtcaaagagagagagcattttccgtgaagtttgaggtccaggctccacgctggggcaacccccgtgcgctcagcttcgtac tgagttcgctccagctcggggagggggtggagttcgatgtgctgcctgcctttgatgccctgggtgagagctcccagcttctttttctccc tcttcccatttctgagcagaaatctcccacagtttgagagctttttgccccaacagggcatctctctaaagcagggtgggaggagatctta ggatctgtcccggggcaagaatgaatacggtcatgatctatcacaggagagacattaaacagcaaattggcataatgtggggacaaa gacatttcttacagaacatctgcaaggcttactggttctgtttaaggcaaaatgtgtgaattttatctttctaaaatcaggcagcaaagatgt ggcttaaagttcatgttactctcatctttgtcccaacatgagatctcatcaaacgtatgcagcacgttgggagatagatatttataatttgcag gaacatttggacaggaagtgtaacctctcagaggctcccttgccacatcaggagaattggtaaaaccacactacctgtatcatatcattat tttaagtgataaatgatcatctacattcagctctgatgagtaataggtgttcaaaaataggaacttccagccaagtgtggtggctcatgctt gtaattccaacacttttggaggctgaggcaggagggtcgcttgagcccaggagttcaagaccagcctgggcagcaaagtgaaacctc atctctactaaaaattttaaaacattagccaagtgtggtggtacatgcctgtggtcgcagttattcaggacgctgagactgaacgatcaca tgaggccagccaaggattcgaggtgtcagtgagccacgaatgtaccactgcactccatcctaggcacagagcaagagcaagaccct gtctcaatcaatcagtcaatcagtcaaaactatgaatttcccagctgtatatgaaggcacctcaaaacaccacagtgaactcacagagg gacacggaatagtttagattttaattttttgagggaaatgcgatgacatctgtcacacaccgcacaaacggctactattaaactgaacttac tgattagtggctactaattaatagttggtcattaagcagtaattagtgattaattatcaagtaattaggacttaattaaaggaactgtcacagtt tcctttagtcctagggcagccatgaaaaaaaaaatgctgactctccaaagacaccagggtatgagaaagttttggattctctcctttgtgc catctcctgtgttgggggctgaagtacaatggttgtaaaagacaagagggagaaggctggtcacagtggctcacgcctgtaatctcag cactttgggaggccaaagtggggggatcacttgaagtcaggaattcaagaccagcctggccaacatggtgaaatctcacatctactaa aaatacaaaaattagctgggcgtggtggtgtgtgcctgtaatcacagctactcgggaggctgaggcaggagaattgcttgaacccagg agatggaggttgcaatgagccaagatcatgccattgcactccagcctgggcaacagagtgagactccatctcgaaaaaaagaaaaaa gaaaagaatataaggagtgattaaaaaagaaaagaaaagaaaactaagtagggtgaaacaatagatagccatgggggttagggagc ttttttagacagggtcgtgagggagggtccctgagcctgagtggcgagaaggagtgagccttggggagatctggaggttctgggaag aggaatggcaagtgcagaggccctgaagcagcaatgaccatggcacatttgaggaagagagaaaaagtcagagaagtagaaagtg ggcaaaggaagcaagacaggaggtgaggtgggagaggttccagagaccagatcacaccagacatcattggccaccataagatcttt gggttttaaaattccagatgttatgggatgcaggaagcagcatgatcagcagcattctctaggtgccaggttgagaacaggctgtgggg gaacctgtaaagaggttgctgccatagttccggcgagtgacggtggtggcttggatggggtgatggcagtggagagggcaggaggg aggatcaggaatggacctcaagacttcccagccctgggtctgctgcacttttcaatcaaaccccatggccagggagattgtcccctcag agtgactgaaggaaattcagagaagagctgacacctaagttgtagattttgcccgaacaggtcagttgactggcggctataaacctaac ccccaaatctatgtcaagctcatcgaggagtgcaccgacctgcagaaagagggcgagttctccacctgcttcacagaactacagaga gacttcctgaagcagcgccccaccaagctcaagagcctcatccgcctagtcaagcactggtaccaaaatgtatggccctcccaccag gcctggtgggtcctgtctcgactgggagcagaggaggggtggggggaggagagaaagaagggagtgaagggaagaggagggg gagtggtggagggaaatagagggatggaaaaaggagagaaaggaaaaagaggtggagagaggagcctgcaacagaagggaga atgaaagggaaggaagagagaaaggaagggattttggtgttctgttcactgctgtatccccagaacttaaaacagagcctggtgcata ataggtgtaaataactgttgaataaatgaatcaatgctacatacacacacgcacgcacacacacacagagagagagtcaaccacactc ttcagaaggtggataagttaaaacaagagtttcaaacaaatatatgttcagatgccctttcctcccacttactggctggctggccttaagta agcaacttaacctttctgttctttctgctttcttatctgcaacgagtagcatgccatagctagagtaacacggcatatagttggtcctgataaa tgtagcatattttagccaccataggagtacacataataaaagctaacatgtagtatgtgcttagcttatctatgttttgtggatgtgatacaatt ttctgttcacttttaaatgccctgcatcttagtcaattttaacagtgattctgtaagttagataaggttaggcattattattaaatccattttacacc aagagaaacttgggtcaaaaagagaaactcctgggtcacatggctcattcggccaataagtagcagaagtaaaatttgaatttggctgg gcgcggtagctcacaccagtaatcccagcactttgggaagccaaggcaggtagattgcttgagcccaggagttcaagactagcctga gcaacatggcaaaacctcgtctctacaaaataaactaaaaatttagccaggtgtgatggtgagcacctgtagccccagctactgggtag gctgaggtgggaggatcgcttgagcctgggaggaggaggttgcagtaagtcaggattgcactactgccctccagcctgtgagacag agcaagatcttctctcaaacaaacaaacaaacaaacaaacaaaaactcgaatttgggtctattgacttaagagtttgcctgataataatag gcattcaatgtatatttcttgaatgaacgaatgaatgaaaataatcaggaataaactttccaatttaaaagtaacacctctaggtaaaaaaa agacaatcatttagttgccagacttctaagtgtttgctgttctatgaattgtaatcatggagcctgagcattgtagaatttacaaaagcagttc ctgacaaaagcagcactgcccccagggacatattgaaaattaatgagggtgtttttggtaaccatggtgatgggaggacatgggtgcta cttatatttagtggaaagaagacaagaatgctagttattgtacaatgatcaagagagtcctgcacagccaagaattgtctttttctttctttctt gatgctgttctcctttaaaacaagacaagattaacaataatttaactccactaaccaccatcatcaccacctccaacttatatgctacatttct tgtatatttcaagtctgtttatattttcaagtgcctcgaagtattattgttttatagccaaatgtttagttaatctgctcacagatttaccactttctt cactattcattctgtcttacacctctaacattccatctggggtaattttcctaaatgatcatgcatcctttgggatttcttttgatgatggtctattg gtagtaaactctctcagttattgtttgtctgaaaatgtcatgcttttgccttcattgttgaagggtgcttttgctgggtggtcatttcagtatattg aatatatcattccatcttccagtgtcatcattaaaaagtcagttgccagtctaactgcagctctttatataagtaacctgtcttattcttctggctg catgtaaaagttttctctttgtctttgattttgtttagcttcaatctgctgtgtcttaatgatgggttcctattgtttgtcctgattgggattccgttaa gattcctgaatctgtgggtagatatctttaatcagttttgaaacttctcagccattcttctaaaatattgattctccttcattctctcctcaccttct agaattccaattaaatgtatgttagaccctgctctatctttcatatctctatactctcttctgtgtttttcatccttttgtctatttttccatgctttattc tgaatagttccttctaatctaccttccaataactaattttctctttagctatatctaatttgctgtaattaattacagttgccatttttatcctaaaatt tctatttcatatttttgtatctgccatggtacttcttatggcttttaattccctgctaactatttaaagttcttattttatcctgtgaatatgatattccta gttattttatttttaatttttattatttgttaatcttatgttttatttacacttcttttctgtgacatgagcacacacagattcatgtgtatacatatatgg ctctgatacctctcctttcctgtcctcattcaaaccactgatcacagagagaggactatttttttttatttttaatttttctatttcaataggtttttgg gggaacaggtggtgtttggttacatgaataagttctttagtggtgattttggtgcacccatcacccaaacagtgtacattgtacccaatgtg taatct tttaacccttgccacaccccaccctttccccgcagtccgcaaagtcccatgtatcattcttatgcctttgcttcctcatagcttagctcccac atatgagtgagaacatacaatgtttggttttccattcctgagttatttaattaaaataatagtatccaattccatccaggttgctgtgaatgcca ttattttgttcctttttatggttgagtagtattccatggtgtgtttgtgtgtgtataacatttttctttatccactcattgattgatgggcatttgggct ggttccatatttttgcaattgcaaattgtgctgttataaacatgtgtgtgcaagtatcttttttgtataatgacttcttttcctctgggtagatacct agtagtgggattgctggatcaaatggtagatctacttttagttctataaggaatctccacactgttttccatagtggttgtatgagtttacattc ccaccaatggtgtaaaagtgttcccttttcaccacatccacaccaacatctattattgtttgattttttattatgaccattcttgcaggagtgag gtggtatcacattgtggttttgatttgcatttccctgataattagggatgttgagcatttttccatatgcttgttggtatttgttttttttttttttttttca ttattatactttaagttttagggtacatgtgcacaatgtgcaggttagttacatatgtatacatgtgccatgctggtgtgctgcacccattaac ccgtcatttagcattaggtatatctcctaatgctatccctccccaattccccccaccccgcttgttggtatttgtatatcttcatttgagaattct ctgttcatgtccttagcccactttttgatgagattttttttttcttgctgattcgtttgagttctttgtagattctggatattagttggatgtatagatt gtgaagattttctcccattctgtgggttgtctgttaactctgctaattatttcttttgctttgcagaagctttttagtttaattaagtcccatctattta tctttgtttttgttgcatttgcttttgggttcttggtcatgaagtctttgcctaagccaatgtgtaggagggtttttccaatattatcttctagaatct ttatggtttcaggtcttagatttaagtatttgatcgattttgagttgaattttgtataaggggagagagaaggattcagtttcattcttctacatg caacttgccaattatcctaggaccatttgttgaatagggtgtcctttccccattttatgtttttgtttggtttgtcaaagatcagttggctgtaagt gtttggctttatttctgggttatctattctgttccatttgtctacgtgactatttttataccagtaccatgttgttttggtgactatggccttacagta tagtttgaagtctgataatgtaatgcctccagatttgttctttttacttagtcttgctttggctatgtgagctcttttttggtgccatatgaattttag gattgttttttctagttctgtgaagaatgatggtggtattttgatgggaattgcattgaatttgtagattgtttttgggagtatggtcattttcaca atattgattctacccattcatgagcatgggatgtgtttccatttgtttgtgtcatctatgattttctttcagcaatgttttgtagttttccttgtagag ttcctagttattttaaagtctgtgttcggtctttcagcatttaaagtttgtaggtttattactatttctcttctttctgttggtcataactcttagtgtttt gtttccttgtgtgcctggttacatatgtgctggtcattgtatttgaaaattatgtgtgaaataatttgaggttttggattatgtatattcctccaga aagaatttcatttgcttctgtgcatttcttaggaacattacaagtccttcttctcagttaattttcgtagtatctttatcagataggtgctattacaa ccactcacttagcagatgaaaatcatgaggctctgagagtctaagtcatctacttagaattggacaatggtgaagccaggattcaaaccc acatcaataagaatccagcgctcttaacaaggggccagtacacttttttaaaaaataaaaggctagatagtaaatattttagactttgtgga ctgcacagcctctgttgcaactactcaaccctgcctttgtagcatgaatgcagtcataaactatacataaatgaatgagcctggattcgttc caaggaaactttataaaaacaggtggcaggctggatttggcccatgagaagtgtagtttacacaaaagttgagcaaaccaatttttttctg attgtttttcctcttctcagtgtaagaagaagcttgggaagctgccacctcagtatgccctggagctcctgacggtctatgcttgggagcg agggagcatgaaaacacatttcaacacagcccagggatttcggacggtcttggaattagtcataaactaccagcaactctgcatctact ggacaaagtattatgactttaaaaaccccattattgaaaagtacctgagaaggcagctcacgaaacccaggtatgctatccccacatgg cttagctcccctatgtaaatgaacacctggatacaggtacagtgccttggaaatggaggaggtgggagggctccccacttagtgagaa tctcctgttgcccatcattgtactgggcattttactactgccatctgttttaaacacctacctccaaccctgtgaggcaggcactatgccaatt attttacaggtgagtaaactgaggttctgagaggtaaggagcttgtccaacccttaacagaaaatgagtaaaatagctgcagtttgaact gaaataagaacagcagcaacaacaatgatagtaattgctcccaggtattgaaagcttgttgtaagactaacacatgctaatataatagta aaaattattagcaatattactgatatgtatgttatgttctagtcgctgtgctgagcatttcatataactgggctttttctatcctcacagcatagc ctttgagataggtatgtggaactattcccattttacagataagaatcctgaggcttagagagttcaagtgacctacccaagggcacatcac tgataaagggcagaggtgggattcaaacccacatctgtcaggtgcaagtgcaaggctccttctcctcatgctcactgcctgctggggaa tagggcactggggacataccccagggagcccttcctcatgttctgagtcccagttcatcccatgctgctattttgctctcccaggagcatc tggactccctagacagagccccagcttctcacctgtccctctctaaatgctgctctgcaggcctgtgatcctggacccggcggacccta caggaaacttgggtggtggagacccaaagggttggaggcagctggcacaagaggctgaggcctggctgaattacccatgctttag aattgggatgggtccccagtgagctcctggattctgctggtgagacctcctgcttcctccctgccattcatccctgcccctctccatgaag cttgagacatatagctggagaccattctttccaaagaacttacctcttgccaaaggccatttatattcatatagtgacaggctgtgctccata ttttacagtcattttggtcacaatcgagggtttctggaattttcacatcccttgtccagaattcattcccctaagagtaataataaataatctcta acaccatttattgactgtctgcttcgggctcaggttctgtcctaagccctttaatatgcactctctcattaaatagtcacaacaatcccatgag gcatttttaaaaatttttattattttagattcagagggcacatgtgccatttgttacacagctatattgtgtaatggtggggtttgggcctctatt gatcctgtcgcccaaatagtgaacagagtacccaaaaagaattttttcaacctttgcctttctcccttcctcctccctgttggagtccctagt gtctattgttcccatctttagcagatgttaagtatttgattttctgtttctgggttaattcacttcggataatggcctccagctgcaaccatgattt cattctttcttatggctgcataatactccatggtgtagatataccacactttctttatccagttcacactgatgggcacttaagttgattccatg actttgctattgtgaatcgtactgcgataaacatacgagtgccggtgtcttttgatagaatgatttctttacctttgggtagataccgagtagt gggattgctgggttgaatggacattctacttttagttatttgaaaagtcccatgaggcatgttttctatcattcccatcttacagatgagacaa aggctcagagaggtgaggtcacttgctcaaggacatcagctaacaagtggtggaaatggaattcaagctcagtggactctaaagcca gtgctcatgtcactgtgctaaacagcctgccttgtcacatccccacctctcatctgaccaatgggagactctgagcagctgagtgacttg ggttgtcacacagctaaacaggggcaaaggacccagtcttggatctttccacctccaagcaggaatctgtctgattccaggggattgat gatgttgcagatggctaggaagcagactccaggatggaatttagtatgcaggatgttctgggggagagccactggaaccagcactca gggaaaggggggaagaaaggataggaaggaagcatgaaagagaatagggagaagtgaacagggatgcagagcgaatgccagtt tcagccaactccaaggacagccctggagctggaatggcctttagagctgccccatggtgacagaggtggccaggcttctataccccta cgtggatcactcactgtgcttgggcaccttgggaaagggcatggctttgagcaaaaggctctctgcagctgaggcaacccctaaaagg gctgacggctgaagtctgtctgctgaccactgtcccagcagctggggcttgttagtccttcctcaaagggggatccagatggcatgtca cagtgtctaccgtaaatgctcactgaatccagctgcaatgcaggaagactccctgatgtgatcatgtgtctcaccctttcaggctgaaag caacagtgcagacgatgagaccgacgatcccaggaggtatcagaaatatggttacattggaacacatgagtaccctcatttctctcata gacccagcacactccaggcagcatccaccccacaggcagaagaggactggacctgcaccatcctctgaatgccagtgcatcttggg ggaaagggctccagtgttatctggaccagttccttcattttcaggtgggactcttgatccagagaggacaaagctcctcagtgagctggt gtataatccaggacagaacccaggtctcctgactcctggccttctatgccctctatcctatcatagataacattctccacagcctcacttca ttccacctattctctgaaaatattccctgagagagaacagagagatttagataagagaatgaaattccagccttgactttcttctgtgcacct gatgggagggtaatgtctaatgtattatcaataacaataaaaataaagcaaataccattta The sequence of the OASI PCR fragment for the G-allele (the G nucleotide is indicated in upper case): (SEQ ID 39) cagatggcatgtcacagtgtctaccgtaaatgctcactgaatccagctgcaatgcaggaagactccctgatgtgatcatgtgtctcaccc tttcaGgctgaaagcaacagtgcagacgatgagaccgacgatcccaggaggtatcagaaatatggttacattggaacacatgagtac cctcatttctctcatagacccagcacactccaggcagcatccaccccacaggcagaagaggactggacctgcaccatcctctgaatgc cagtgcatcttgggggaaagggctccagtgttatctggaccagttccttcattttcaggtgggactcttgatccagagaggacaaagctc ctcagtgagctggtgtataatccaggacagaacccaggtctcctgactcctggccttctatgccctctatcctatcatagataacattctcc acagcctcacttcattccacctattctctgaaaatattccctgagagagaacagagagatttagataagagaatgaaattccagccttgac tttcttctgtgcacctgatgggagggtaatgtctaatgtattatcaataacaataaaaataaagcaaataccatttattgggtgtttattaactt caaggcacagagccaagaagtacagatgcatatctaggggtattgtgtgtgtatatacattgattcaacaagaaatatttattgagcactt actatgtgccaagcatagctctgg The sequence of the OAS1 PCR fragment for the A-allele (the A nucleotide is indicated in upper case): (SEQ ID 40) cagatggcatgtcacagtgtctaccgtaaatgctcactgaatccagctgcaatgcaggaagactccctgatgtgatcatgtgtctcaccc tttcaAgctgaaagcaacagtgcagacgatgagaccgacgatcccaggaggtatcagaaatatggttacattggaacacatgagtac cctcatttctctcatagacccagcacactccaggcagcatccaccccacaggcagaagaggactggacctgcaccatcctctgaatgc cagtgcatcttgggggaaagggctccagtgttatctggaccagttccttcattttcaggtgggactcttgatccagagaggacaaagctc ctcagtgagctggtgtataatccaggacagaacccaggtctcctgactcctggccttctatgccctctatcctatcatagataacattctcc acagcctcacttcattccacctattctctgaaaatattccctgagagagaacagagagatttagataagagaatgaaattccagccttgac tttcttctgtgcacctgatgggagggtaatgtctaatgtattatcaataacaataaaaataaagcaaataccatttattgggtgtttattaactt caaggcacagagccaagaagtacagatgcatatctaggggtattgtgtgtgtatatacattgattcaacaagaaatatttattgagcactt actatgtgccaagcatagctctgg

FIG. 1 shows physical and transcript maps of the Flv interval. Genes are represented by their accepted abbreviations or the GenBank accession numbers of their transcripts. The arrows represent the direction of gene transcription. The centromere is oriented toward the left of the figure, The Oas1b gene is indicated in bold. The flanking microsatellite markers are shown inside vertical rectangles, the D5Mit159 marker is shown inside a horizontal rectangle. The horizontal bars beneath the gene s represent the BAC clones listed by the library name.

Twenty-two candidate genes for the Flv gene which controls resistance or susceptibility to flavivirus disease were identified. Full-length cDNAs were amplified by RT-PCR from congenic flavivirus resistant (C3H.PRI-Flv^(r)) and susceptible (C3H/He) mouse strains for each gene identified in the Flv region using the primers listed in Table 2, sequenced and compared. The sequences of the majority of the genes in the two mouse strains were either identical or very similar (with only a few silent substitutions). In contrast, two genes, Na+/Ca2+-exchanger and Oas1b, were polymorphic and differed by several missense mutations. The Na+/Ca2+-exchanger cDNA from the C3H.PRI-Flv^(r) and C3H/He mouse strains differed by five non-synonymous substitutions (data not shown). cDNAs for this gene were subsequently sequenced from two additional susceptible (BALB/c and C57BL/6) and one additional resistant (BRVR) mouse strains. A random distribution of substitutions in the Na⁺/Ca²⁺-exchanger cDNAs were observed between the five mouse strains studied.

A total of 31 substitutions in Oas1b cDNA were found between the congenic C3H.PRI-Flv^(r) and C3H/He mouse strains. Most of these substitutions were silent, but the C820T transversion, in the susceptible C3H/He strain resulted in a premature stop-codon. The C3H/He Oas1b gene product therefore lacked 30% of its C-terminal sequence as compared to the C3H.PRI-Flv product (FIG. 2A). Two additional non-synonymous mutations resulted in a threonine to alanine substitution at position 65 and an arginine to glutamine substitution at position 190 in the susceptible C3H/He gene product.

FIG. 2 illustrates the structures of the Oas lb gene and protein. A. Domain architecture of Oas lb proteins. The N-terminal domain (˜30 aa) (shown in gray) and the C-terminal domain (shown in black) are specific to the Oas protein family (generated with the ProDom tool). The nucleotidyltransferase domain (Pfam 01909) is shown in white. The CFK tetramerization motif is indicated by an asterisk. (1) Products of the Flv^(r) and Flv^(r)-like alleles. (2), Product of the Flv^(mr) allele. (3), Product of the Flv^(s) allele. Positions of amino acid substitutions between the Flv^(mr) and the Flv^(r) proteins are shown as vertical bars. B. Exon-intron structure of the mouse Oas1b gene. Exons are shown as open boxes. The positions of the start (ATG) and stop (TAG) codons, the substitution (CGA/TGA) that results in a premature stop codon and the two potential polyadenylation sites are indicated by vertical lines.

Comparison of Oas1b genomic (AC015535) and cDNA (AF328926) sequences revealed six exons. Based on the results of the 5′ RACE experiments, the size of the first exon was determined to be 243 bp in length and included 64 bp of the 5′ non-coding region (NCR). The lengths of the second, third, fourth and fifth exons were 277, 185, 233 and 154 bp, respectively. The fourth exon of Oas1b in the susceptible strain contained a premature stop-codon (FIG. 2B). All exon-intron boundaries contained conventional splicing sites. In the resistant strain, the sixth exon included the last 102 bp of the ORF and the 3′ NCR, which contained two potential polyadenylation signals separated by about 2 kb.

The individual exons of the Oas1b genes from eight additional mouse strains were next amplified from genomic DNA and sequenced. The Oas1b gene encodes an identical full-length protein in all resistant strains (BRVR, C3H.PRI-Flv^(r), CASA/Rk, and CAST/Ei), whereas the homologous gene from all susceptible strains (129/SvJ, BALB/c, C3H/He, C57BL/6, and CBA/J) encodes an identical truncated protein. The flavivirus susceptibility phenotype correlated with the Oas1b genotype in all nine mouse strains studied.

The Oas1b protein contains three domains (FIG. 2A). The N- and the C-terminal domains are unique to the 2′-5′ oligoadenylate synthetase family, whereas the central domain has a distinct nucleotidyltransferase fold. Several motifs were previously detected in murine 2′-5′ oligoadenylate synthetases (FIG. 6). FIG. 6 shows alignment of the protein sequences of the murine, rat and human 2′-5′ oligoadenylate synthetases. Conserved positions within known functional motifs are colored according to the physico-chemical properties of amino acid residues: hydrophobic residues are highlighted in yellow, charged residues are shown in a white or red background and small residues are shown in a white or blue background. The domain structure is shown above the alignment and corresponds to that shown in FIG. 2A. An N-terminal LxxxP motif is required for 2′-5′ oligoadenylate synthetase activity (30), whereas the P-loop motif is responsible for dsRNA binding (31). It has also been shown that a DAD Mg²⁺ binding motif is required for normal functioning of the murine 2′-5′ oligoadenylate synthetase (32). Although the LxxxP and DAD motifs were conserved in the products of both the resistant and susceptible alleles of the Oas1b gene, the P-loop motif contained a four amino acid deletion that was not found in the other murine 2′-5′ oligoadenylate synthetases (FIG. 6). A C-terminal CFK motif appears to be critical for tetramerization of the small form of mouse 2′-5′ oligoadenylate synthetase (33). The truncated susceptible Oas1b protein does not contain the CFK motif and so could not form the tetramer structure required for 2′-5′ oligoadenylate synthetase activity.

Although the Oas1b cDNA sequence from the MOLD/Rk strain (intermediate Flv phenotype) also encodes a full-length protein, it differs from the proteins of the other resistant strains by 14 amino acid substitutions, F26L, S45F, G63C, T65A, S83Y, C103Y, F110C, H118Q, P176L, S183L, 1184T, T322A, G347A and M350T, distributed randomly across the protein (FIG. 2A). The MOLD/Rk Oas1b protein sequence contains alanine at position 65 similar to the proteins encoded by the susceptible strains. The MOLD/Rk Oas1b sequence differs by two substitutions, L26F and R206H, from the recently released sequence, AAH12877, derived from the CZECH II mouse strain, which has an unknown Flv phenotype. Both MOLD/Rk and CZECH-II contain the same four amino acid deletion in the P-loop motif found in all Oas1b proteins.

Investigations of the constitutive expression of the Oas1b gene in different mouse tissues were conducted. Although alpha/beta-interferon treatment up-regulated the transcription of the murine Oas1b gene (data not shown), constitutive expression of this locus was detected by Northern blotting in all 14 murine tissues tested. Two transcripts of the expected sizes, 2 kb and 4 kb (FIG. 3), were identified using a labeled cDNA probe derived from the 3′ NCR of Oas1b (cDNA positions 1384-1691 bp). The highest levels of constitutive expression were detected in lung and spleen (FIG. 3), thymus, placenta and uterus (data not shown).

FIG. 3 shows the constitutive expression of mouse Oas1b in different mouse tissues. A labeled Oas1b probe derived from the 3′ NCR of Oas1b was used to probe a BALB/c Northern blot (Stratagene) containing poly-A⁺ RNA (2 μg/lane) extracted from: 1, heart; 2, kidney; 3, liver; 4, lung; 5, skeletal muscle; or 6, spleen.

The effect of expression of C3H.PRI-FLV^(r) proteins in C3H/He cells on flavivirus replication was investigated. Since the Flv^(r) allele is dominant, its expression in susceptible cells was expected to have a dominant negative effect on flavivirus replication. C3H/He cells were transfected with the mammalian expression vector pEF6/V5-His-TOPO containing either the Oas1b or the Na⁺/Ca²⁺-exchanger cDNA from C3H.PRI-Flv^(r). Stable cell lines were established by selection and cloning of transfected cells. The growth of the flavivirus, WNV, in susceptible C3H/He cell lines expressing either the Na⁺/Ca²⁺-exchanger or the Oas1b protein from resistant C3H.PRI-Flv^(r) was compared to that in untransfected C3H/He and C3H.PRI-Flv^(r) cells. No differences were observed either in the yields of WNV or in the time of appearance of cytopathic effect (CPE) between cell lines expressing the Na⁺/Ca²⁺-exchanger protein and untransfected C3H/He cells (data not shown). However, in C3H/He cell lines expressing a low level of the resistant Oas1b protein, viral titers were lower than those observed in untransfected cells, but not as low as in untransfected C3H.PRI-Flv^(r) cells (FIG. 4A).

FIG. 4 shows the effect of the low level expression of the resistant Oas1b protein in C3H/He cells on the growth of a flavivirus, West Nile virus, and an alpha togavirus, Sindbis. A. Virus growth curves. Cells were infected with either West Nile or Sindbis virus at a MOI of 0.5. Samples of culture fluid were taken at the indicated times and titered by plaque assay on BHK cells. RU, untransfected resistant C3H.PRI-Flv^(r) cells; SU, untransfected susceptible C3H/He cells; ST, susceptible C3H/He cells stably transfected with Oas1b cDNA from resistant C3H.PRI-Flv^(r) cells. B. Time course of the development of cytopathic effect (CPE) after infection of SU, RU and ST cells with West Nile virus. −, no obvious CPE; +, rounding or detachment of about 25% of the cells in the monolayer; ++, rounding or detachment of about 50% of the cells in the monolayer; +++, rounding or detachment of about 75% of the cells in the monolayer; ++++, complete destruction of the monolayer.

The appearance of CPE in C3H.PRI-Flv^(r) cells after WNV infection was significantly delayed as compared to that in C3H/He cells. The appearance of CPE was also delayed in C3H/He cells expressing the resistant Oas1b (FIG. 4B). In contrast, the growth and the time of appearance of CPE of an alpha togavirus, Sindbis, were similar in the three types of cells. The recombinant Oas1b protein contained both C-terminal 6×His and V5 tags which may have interfered with the activity of the 2′-5′ oligoadenylate synthetase by reducing the efficiency of tetramer formation. Surprisingly, cell lines expressing intermediate levels (8×) of resistant Oas1b protein showed lower levels of WNV suppression, while those expressing high levels (20×the protein showed no suppression (data not shown). The reasons for a negative correlation between suppression of WNV replication and the level of resistant protein expressed are currently not understood. Experiments to produce and test knock-in mice are underway.

The N-terminal 346 amino acids of OAS1 represent one functional unit, while OAS2 and OAS3 contain two and three functional units, respectively (19, 34-36). The murine Oas sequences obtained previously by different laboratories were named without knowledge of the entire gene family and designated by different symbols. A proposed simplified nomenclature for the murine Oas gene family is shown in Table 1. The single functional unit sequences were designated Oas1a through Oas1h, whereas the two- and three-unit sequences were designated Oas2 and Oas3, respectively (FIG. 1 and Table 1).

The 2′-5′ oligoadenylate synthetase-like genes, OASL and Oas12 have recently been cloned from humans (36-37) and mice (38), respectively. A Celera database search revealed an additional murine gene, Oas11, which was located close to Oas12 and was about 6 Mb upstream the Oas2 locus. All of the human and mouse 2′-5′ oligoadenylate synthetase-like genes contained C-terminal ubiquitin-like domains. Although the Oas-like 1 (Oas11) gene was mapped outside of the Flv interval, the cDNA of this gene was cloned and sequenced so that the comparative analysis of 2′-5′ oligoadenylate synthetase motifs included all of the known family members.

Available protein sequences for murine, rat and human 2′-5′ oligoadenylate synthetases were aligned and a phylogenetic tree was constructed (FIG. 5). The known rat proteins, AAC19135 and CAA79317, are encoded by two genes orthologous to murine Oas1b and Oas1a, respectively. Six additional rat Oas1 sequences have now been seqenced and are attached. All rodent Oas1 sequences cluster with the single human ortholog, OAS1. This clustering was fully supported by bootstrap analysis. The existence of eight apparent Oas1 paralogs in mice likely resulted from a series of gene duplication events. The one-to-many orthologous relationship between human and murine genes is unique to Oas1 and was not -observed for other members of the Oas family (FIG. 5). FIG. 5 shows unrooted neighbor-joining, distance-based phylogenic tree of murine, rat and human Oas sequences. Human genes are designated by capital letters, while only the first letter is capitalized for the mouse genes. The sequences of the Oas2 and OAS2 proteins were divided into N- and C-terminal domains according to (19). The sequences of Oas3 and OAS3 proteins were divided into N-terminal (N), middle (M) and C-terminal (C) domains. The indicated bootstrap values were obtained with 1000 pseudoreplicates. The Oas1 cluster is shown on a gray background. The bar indicates the number of substitutions per site.

Twenty-two loci, including thirteen novel genes [a Ca²⁺-channel gene (AF217002), an unknown mRNA (AF217003), an ATP-dependent helicase (AF319547), a serine dehydratase (AF328927), a Na⁺/Ca²⁺ exchanger (AF217002), the Oas1b (AF328926), the Oas1d (AY055829), the Oas1e (AY055830 and AY055831), the Oas1f (AF481733), the Oas1g (AF480417), the Oas2 (AF418010), the Oas3 (AF453830), and the Oas11 (AY057107)] were detected in a region of mouse chromosome 5 during positional cloning of the Flv gene. The D5Mit159 microsatellite sequence used for the initial BAC library screening was detected in the second intron of the Ca²⁺-channel gene (AF217002). By correlation of a polymorphism in the Oas1b gene with the susceptibility phenotypes of nine strains of flavivirus resistant and susceptible mice, the Flv gene was identified as Oas1b, a member of the 2′-5′ oligoadenylate synthetase gene family. 2′-5′ oligoadenylate synthetases bind dsRNA or particular secondary structures within single-stranded RNA (ssRNA) and catalyze the synthesis of 2′-5′ oligoadenylates (2-5A) from ATP (39). A major function of 2-5A is to bind and activate a latent endoribonuclease, RNase L, responsible for the degradation of viral and cellular ssRNAs (40). 2′-5′ oligoadenylate synthetases are also involved in other cellular processes such as apoptosis, cell growth and differentiation, regulation of gene expression, DNA replication and RNA splicing (19).

Data obtained with the three types of human 2′-5′ oligoadenylate synthetases, OAS1, OAS2, and OAS3 indicate that OAS3 functions as a monomer, while OAS2 and OAS1 are enzymatically active only as a homodimer and a homotetramer, respectively (19). The Oas1b genes from resistant mice encode full-length proteins, while those from susceptible mice encode C-terminally truncated proteins. Since the C-terminal region of the single-unit proteins is required for tetramerization, which is crucial for 2′-5′ oligoadenylate synthetase activity, it is likely that the Oas1b proteins produced by susceptible mice are not active. The OAS1, OAS2 and OAS3 genes are differentially induced by interferons alpha, beta and gamma in various tissues (19). Although the expression of the mouse Oas1b gene was up-regulated after incubation with alpha/beta-interferon, it was found to be constitutively expressed at low levels in both resistant and susceptible cells (data not shown). These results are consistent with the previous observation that flavivirus resistance was not diminished in resistant mice after injection of anti-alpha/beta interferon antibody (41).

The effect of the Flv gene product is virus-specific, since it suppresses the replication of the members of the genus Flavivirus, but has no effect on the replication of other types of viruses. The functions of 2′-5‘A and the latent endoribonuclease, RNase L are both non-specific. The Oas1b proteins from both resistant and susceptible mice differ from other 2′-5’ oligoadenylate synthetases by one unique change, a four amino acid deletion within the P-loop motif. The P-loop region is involved in RNA recognition and binding and may allow the Oas1b protein to specifically recognize and bind a specific conserved RNA structure unique to flavivirus RNAs. In support of this hypothesis, Urosevic and co-authors (42) reported that the ORI 56 strain of Murray Valley encephalitis virus, which had a 62-nucleotide deletion in its 3′non-coding region (43), replicated more efficiently in resistant mice than did strains of this flavivirus with full-length RNAs. Results from previous sucrose gradient analyses (10) and recent RNase protection experiments (data not shown) indicate that the levels of genomic flavivirus RNA, but not anti-genomic RNA, are preferentially reduced in flavivirus infected resistant cells as compared to susceptible cells. Also, more flavivirus dsRNA and less viral ssRNA were detected in the brains of resistant mice as compared to those of susceptible animals (44). Since genomic RNA is found free in the cytoplasm, it would be more susceptible to digestion by RNase L than would anti-genomic RNA, which is only present in double-stranded replication intermediate RNA structures. Since the Oas1b proteins from both resistant and susceptible mice have the same four amino acid deletion in the P-loop motif, both proteins would be expected to bind specifically to flavivirus RNAs, but RNA binding would only activate the full-length resistant Oas1b protein. It is currently not known whether the 2′-5′ oligoadenylate synthetase activity alone is sufficient to confer the flavivirus resistant phenotype or whether as yet uncharacterized activities of the Oas1b protein also contribute. Even though the Flv^(mr) proteins also had the same deletion in the P-loop motif, the additional amino acid substitutions in these proteins were apparently responsible for the reduced level of resistance observed in this strain. This suggests that additional regions of the Oas1b may also be functionally important for susceptibility. Functional studies with a recombinant Oas1b protein are currently underway to address these questions. The advantage provided to mice. and possibly to other rodents by the large number of Oas1 genes is currently not understood. Some of the mouse Oas1 gene products are not active synthetases, including Oas1b. Preliminary data suggest that an inactive synthetase such as Oas1b can enhance the enzymatic activity of an active synthetase. One mechanism by which this could occur would be via the formation of heterotetramers. The formation of different heterotetramers could regulate activity levels. The Oas1 gene products may also interact with other cell proteins to accomplish additional as yet unknown functions.

Prior to the current invention, inherited flavivirus resistance appeared to be restricted to Mus species. Rats have multiple Oas1 genes and an Oas1b ortholog (AF068268), but resistance to flaviviruses has not yet been studied in rats. Humans have only a single OAS1 gene, but this gene produces multiple isoforms via alternative splicing (FIG. 7).

Human OAS proteins, OAS1, OAS2, OAS3 and-OAS-like, are 2′,5′-oligoadenylate synthetases. The members of this family of interferon-induced proteins function in the antiviral action pathways of interferon but also have functions in gene regulation, apoptosis and development. When activated by double-stranded RNA, these proteins polymerize ATP into 2′,5′-linked oligomers with the general formula pppA(2′p5′A)_(n). This mixture of oligonucleotides is known as 2-5A and currently it is believed that 2-5A binds and activates a latent endoribonuclease responsible for the degradation of viral and cellular RNAs.

Resistance to infection by flaviviruses has been associated with variations in human OAS genes, particularly OAS1. The current invention also contemplates that mutations in other OAS genes may also be important for virus resistance/susceptibility.

When the G is present (G-allele) in the human OAS1 gene at nt position. 12,349 (numbered beginning from the ATG-start codon in the genomic DNA) (FIG. 8; Celera SNP accession number hCV2567433) the OAS1 transcripts encoding the p46 and p48 isoforms are produced as a result of alternative splicing events. The conventional splicing acceptor “ag” at the end of intron 5 is utilized for processing of the p46 mRNA. Utilization of a different splice acceptor located 96 nucleotides downstream from the conventional intron 5 acceptor results in the production of the p48 mRNA.

When an A is present (A-allele) at OAS1 nucleotide position 12,349, the splice acceptor site is mutated to a non-functional “aa” and the p40 mRNA is produced by read-through into intron 5 (FIG. 8). An additional splice acceptor (aG, where G is the +1 nucleotide located at the beginning of the conventional exon 6) can alternatively be utilized to produce p52 mRNA designated hCT31628 in the Celera human transcript database. The p48 transcript can also be produced by individuals with the A-allele. The 346 N-terminal amino -acids of the p40, p46, p48, and p52 are identical but their C-terminal regions differ due to alternative splicing. Each of the isoforms has a unique C-terminus translated from different ORFs. Stop-codons for the ORFs encoded by p46, p48 and p52 transcripts are located in exon 6 at positions +163/+165, +303/+305, and +341/+343, respectively. The stop-codon for the p40 transcript is located at position +54/+57 in intron 5.

Data from a study of human populations indicated that the different alleles of the OAS1. gene are important for determining viral resistance/susceptibility. The frequency of the A-allele in ethnic Russian populations who are known to be highly resistant to disease caused by the flavivirus, tick borne encephalitis virus, was significantly increased (up to 99%) as compared with the frequency in a group of non-ethnic patients with tick home encephalitis virus-induced disease (59%). The GG homozygpus individuals exhibited the most severe disease symptoms. No GG-homologous individuals were detected in the native Siberian populations. In contrast, the frequencies of the A-allele and the G-allele were similar in groups of healthy Russians and Russians infected with hepatitis C virus (a distantly related member of the flavivirus family from a different genus. The data is summarized in Table 1. TABLE 1 Human Viral Resistance Genotypes Frequencies and Frequencies numbers of genotypes of alleles Population N AA AG GG A G Russians 134 0.69 (93) 0.28 (37) 0.03 (4) 0.83/0.71* 0.17/ 0.29* Altains 30 0.70 (21) 0.30 (9)  0.00 (0) 0.85 0.15 Chukchi 114 0.85 (97) 0.15 (17) 0.00 (0) 0.93 0.07 Tuvinians 42 0.98 (41) 0.02 (1)  0.00 (0) 0.99 0.01 TBE 22 0.36 (8)  0.45 (10) 0.19 (4) 0.59 0.41 patients *Data from two genotypings.

Linkage with additional polymorphisms located in exon 6 has been observed (Table 2). TABLE 2 Linkage disequilibrium of A/G mutations in the intron 5 acceptor site (hCV2567433) with additional SNPs in exon 6 of the OAS1. hCV2567433 rs3177979 rs1051042 hCV2567429 hCV2567429 + 1nt AA AA CC AA AG GG GG GG GG GG

The G-allele linked mutations in exon 6 would cause the following amino acids changes: 352A and 361R in p46 and 397G in p48. The A-allele linked mutations in exon 6 would cause the following amino acid changes: 397K/R in p48 and 361R and 429K in p52. Some or all of these additional changes may also be functionally relevant. Data also shows that mutations in other human OAS genes may be relevant in determining viral resistance/susceptibility (Table 3). TABLE 3 Frequencies of genotypes and alleles in OAS2 and OAS3 SNPs. OAS2 SNP rs15895 OAS3 SNPs rs2285932 Genotypes Alleles Genotypes Alleles Population N AA AG GG A G CC CT TT C T Altaians 30 0.00 0.43 0.57 0.13 0.87 0.70 0.30 0.00 0.85 0.15 TBE patients 18 0.12 0.44 0.44 0.33 0.67 0.33 0.44 0.23 0.56 0.44

The methods of the present invention comprise the identification of resistant genotypes. By sequencing a human resistance/susceptibility gene, such as the OAS1 gene, specific sequences were identified that were cleaved by a specific restriction endonuclease. A method for identifying the genotype of an individual comprises cleaving a nucleic acid sample from an individual with one or more specific endonucleases that are known to differentiate between viral resistant genotypes. The pattern is observed after separating the cleaved nucleic acid segments by electrophoresis on a gel and used to determine the genotype of the source of the nucleic acid sample.

About 20 ng of human genomic DNA was amplified by PCR for each sample using the HO1-F forward primer (5° CAGATGGCATGTCACAGTGTCTAC 3′) and the HO1-R reverse primer (5° CCAGAGCTATGCT.TGGCACATAGT 3′) in a total volume of 25 microliters. After amplification, 5 microliters of restriction mix containing 3 microliters of 10× restriction buffer, 10 units of Alu I endonuclease, and 1 microliter of distilled water were added directly to each PCR tube and incubated for 1 hour at 37° C. Restriction reactions were resolved on 2% agarose gels, stained with ethidium bromide and the gels were photographed under UV light. Other visualization or measurement-methods are contemplated by the present invention. There are four AluI-recognition sites in the PCR product derived from the G-allele. AluI digestion of this product generates two large restriction fragments of 378 bp and 306 bp as well as three short (invisible) restriction fragments of 46 bp, 12 bp, and 8 bp, respectively. In PCR DNA containing the A-allele, an additional AluI restriction site is present which would divide the 306 bp fragment into a large 255 bp fragment and a short (invisible) 51 bp fragment. Therefore, the AluI restriction pattern of the G-allelic variant contains a unique visible fragment of 306 bp, while that of the A-allelic variant contains a unique visible fragment of 255 bp on the agarose gel (FIG. 9). There are no isoschizomers for AluI. There are currently no additional known restriction enzymes specific for the sequence around the mutation. Additional techniques that could be used for genotyping of this mutation are: 1). Direct sequencing of region containing the mutation; 2). A SNP assay using single nucleotide extension by Real Time PCR; 3). Microchip hybridization. The methods are well known to those skilled in the art.

Compositions of the present invention comprise endonucleases, solutions and buffers necessary for cleaving of DNA samples. Additionally, reference DNA samples of resistant and susceptible genes are included. Preferred compositions are found in kits for testing the genotypes of individuals. Other compositions included in the present invention comprise constructs and vectors comprising the relevant sequences, cell lines derived from individuals that have different alleles, which affect their virus resistance/susceptible phenotype, which could be used for comparing the efficacy of candidate antiviral agents or strategies under different host-virus conditions. Additionally, the present invention comprises compositions comprising cell lines transformed by the relevant sequences comprising the resistant or susceptible variants.

The present invention comprises methods and compositions for determining viral resistance/susceptibility by indentifying the genotype of the human or animal. Alleles of the OAS genes are one set of indentifiable genes that determine viral resistance/susceptibility. Identifying these alleles in a human or animal, either alone or in combination with other genes, determines the resistance/susceptibility to viral infection, particularly flavivirus infection. For example, seven single nucleotide polymorphisms (SNPs) were genotyped within the human locus encoding interferon-inducible double stranded RNA dependent protein kinase (PRKR). Two of these SNPs, rs4648174 and rs2287350, showed complete linkage disequilibrium (always segregated together) in 122 Russian DNA samples tested. However, in 44 DNA samples from TBEV-induced disease patients, the genotype distribution of these two SNPs in 20 patients with febrile disease (fever) differed significantly (χ²=12.4; P=0.002) from that in 24 patients with severe disease (meningitis, encephalitis and/or poliomyelitis). These data suggest that variation in additional innate immune system genes, such as PRKR, could also be associated with the severity of flavivirus-induced disease in humans. The present invention comprises methods and compositions for identifying OAS alleles and other genes for determining the extent of flavivirus infection, severity of viral disease, and susceptible/resistant populations, among other aspects of viral disease.

Methods of the present invention are not limited to the viruses described herein, but include methods for determining the genotype of individuals for a resistant or susceptible response to any virus for which an interferon response is made by the body. Preferred methods comprise determining the genotype of an individual, particularly for OAS alleles, including OAS1, OAS2, OAS3 and OAS-like alleles, using selective endonuclease characterization of the individual's DNA.

Sequences disclosed herein: (SEQ ID 1) LOCUS AF217002  2742 bp mRNA linear ROD 25-JUN-2002 DEFINITION Mus musculus calcium channel mRNA, complete cds. ACCESSION AF217002 translation = “MAVSLDDDVPLILTLDEAESAPLPPSNSLGQEQLPSKNGGSHSI HNSQVPSLVSGADSPPSSPTGHNWEMNYQEAAIYLQEGQNNDKFFTHPKDARALAAYL FVHNHFFYMMELLTALLLLLLSLCESPAVPVLKLHTYVHATLELFALMVVVFELCMKL RWLGFHTFVRHKRTMVKTSVLVVQFIEAIVVLVRQTSHVRVTRALRCIFLVDCRYCGG VRRNLRQIFQSLPPFMDILLLLLFFMIIFAILGFYLFSTNPSDPYFSTLENSIVNLFV LLTTANFPDVMMPSYSRNPWSCVFFIVYLSIELYFIMNLLLAVVFDTFNDIEKHKFKS LLLHKRTAIQHAYGLLASQRRPAGISYRQFEGLMRFYKPRMSARERFLTFKALNQSNT PLLSLKDFYDIYEVAALQWKAKRNRQHWFDELPRTAFLIFKGINILVNSKAFQYFMYL VVAVNGVWILVETFMLKGGNFTSKHVPWSYLVFLTIYGVELFMKVAGLGPVEYLSSGW NLFDFSVTAFAFLGLLALTLNMEPFYFIVVLRPLQLLRLFKLKKRYRNVLDTMFELLP RMASLGLTLLTFYYSFAIVGMEFFNGRLTPNCCNTSTVADAYRFINHTVGNKTKVEEG YYYLNNFDNILNSFVTLFELTVVNNWYIIMEGVTSQTSHWSRLYFMTFYIVTMVVMTI IVAFILEAFVFRMNYSRKSQDSEVDSGIVIEKEMSKEELMAVLELYREERGTSSDVTR LLDTLSQMEKYQQNSMVFLGRRSRTKSDLSLKMYQEEIQEWYEEHAREQEQQKLRGSV PGPAAQQPPGSRQRSQTVT” BASE COUNT 568 a 819 c 727 g 628 t ORIGIN 1 aaggctggcg cagctgccgc tgtggcagcg gtgaggcggc ggtggcggct gctgaggctc 61 cgcgctgggg atattggcgg cggcaactgc gggctgagct acgctgtgca gacccagtgc 121 acagtgcggg atcccgggac ggcgcgtacc ttagaagatg cctctgatgg aacaggctct 181 gggaagcttc cccggccccg tggctttgaa caggagctca agccggaggc agtttaaagc 241 cctggccgtt gtatcctgag gaccgcaggt caggagaaga tggctgtaag tttagatgac 301 gatgtgccgc tcatcctgac cttggacgag gctgagagtg ctccgctgcc tccttcgaac 361 agcctgggcc aagagcagct gcccagcaaa aatgggggca gccacagcat ccacaactcc 421 caggtcccca gtctggtctc cggagcggac agccccccct ccagtcccac cggacacaac 481 tgggagatga attatcaaga ggcggcaatc tacctccagg aaggtcagaa caacgacaag 541 ttcttcaccc accccaagga tgccagagcg ctggcggcct acctcttcgt ccacaaccac 601 ttcttctaca tgatggagct gctcacggcc ctgctcctgc tgctgctgtc gctgtgcgag 661 tcccccgctg tccccgtgct caagctgcac acttacgtcc acgccacgct ggaactcttt 721 gccctcatgg tggtggtatt tgaactctgc atgaaattgc ggtggctggg cttccacacg 781 ttcgtccggc acaaacgtac catggtcaag acgtccgtcc tcgtggtgca gttcatcgag 841 gccattgtgg tgctggttcg gcagacgtcc cacgtgcggg tgacccgggc actacgctgc 901 attttcctgg tggactgtcg ctactgtggc ggtgtacggc gcaacctgcg gcagatcttc 961 cagtctctcc cacccttcat ggacatcctc ctgttgctgc tcttctttat gatcatcttt 1021 gccatcctcg gtttctactt attctccaca aatccttccg acccctactt cagcaccctg 1081 gagaacagca tcgtcaacct gttcgttctc ctgaccacag ccaactttcc agatgtcatg 1141 atgccctcct actcccggaa cccctggtcc tgcgtcttct tcattgtata cctctccatt 1201 gagctgtact tcatcatgaa cctgctcctg gccgtggtgt tcgacacctt caacgacatt 1261 gaaaagcaca agttcaagtc tttgctgctg cacaaacgga ccgccatcca gcatgcctac 1321 ggcctgcttg ccagccaacg gaggccggct ggcatctcct acaggcagtt cgaaggctta 1381 atgcgcttct acaagccccg gatgagtgca agggaacgct tcctgacttt caaggccttg 1441 aaccagagca acacgcctct gctcagcctg aaggacttct atgatattta cgaagtcgct 1501 gctctgcagt ggaaggcaaa gagaaacaga cagcattggt ttgatgagct cccccggaca 1561 gccttcctca tcttcaaagg gattaacatc cttgtgaatt ccaaggcctt ccagtatttc 1621 atgtacttgg tggtggctgt caacggtgtc tggatcctgg tggagacatt catgttgaaa 1681 ggtgggaatt tcacctcaaa gcatgtgccc tggagttacc tcgtgtttct taccatctat 1741 ggagttgaac tgttcatgaa ggtggctggc ctgggccctg tggagtacct gtcctctgga 1801 tggaacctgt tcgatttctc ggtcacggca ttcgccttcc tgggactgct cgcactgacg 1861 ctcaacatgg aacccttcta tttcattgtg gtcctgcgtc cccttcagct gctgaggtta 1921 tttaaactga agaaacgcta ccgcaacgtg ttggacacca tgtttgagct gctgccgcgg 1981 atggccagcc ttggcctcac gctgctcacc ttctactatt ccttcgccat cgtgggcatg 2041 gagttcttca acgggcggct gacccccaac tgctgcaaca ccagcacagt ggccgacgcc 2101 taccggttca tcaaccacac tgtgggcaat aagaccaagg tagaggaagg ctactactat 2161 ctcaacaact ttgacaacat cctcaacagc ttcgtgacct tgtttgagct caccgttgtc 2221 aacaattggt acatcatcat ggaaggcgtc acctcgcaga cgtcccactg gagccgcctg 2281 tacttcatga ccttttacat agtgaccatg gtggtgatga ccattatcgt ggccttcatc 2341 ctggaggcct tcgtcttccg catgaactac agccgcaaga gccaggactc ggaagtggac 2401 agtggcatcg tcatcgagaa ggaaatgtcc aaggaggagc ttatggccgt cctggagctt 2461 tatcgtgagg agcgaggcac ctcctctgac gtgacccggc tgctggacac cctctctcag 2521 atggagaaat accagcaaaa ttccatggtg tttctgggac ggcgatcgag aaccaaaagt 2581 gacctgagtc tgaagatgta ccaggaggag atccaggagt ggtacgagga gcatgcccgg 2641 gaacaggagc agcagaagct caggggcagc gtgcccggcc ctgcagccca gcagccccct 2701 ggcagtcgcc agcgctccca gactgtcacc tagctgggtt tc // (SEQ ID 2) LOCUS AF217003  3569 bp mRNA linear ROD 25-JUN-2002 DEFINITION Mus musculus unknown mRNA. ACCESSION AF217003 /translation = “MAAPVDGSSGGWAARALRRALALTSLTTLALLASLTGLLLSGPAGALP TLGPGWQRQNPDPPVSRTRSLLLDAASGQLRLEDGFHPDAVAWANLTNAIRETGWA YLDLSTNGRYNDSLQAYAAGVVEASVSEELIYMHWMNTVVNYCGPFEYEVGYCEKL KNFLEANLEWMQREMELNPDSPYWHQVRLTLLQLKGLEDSYEGRLTFPTGRFTIKPLG FLLLQISGDLEDLEPALNKTNTKPSLGSGSCSALIKLLPGGHDLLVAHNTWNSYQNML RIIKKYRLQFREGPQEEYPLVAGNNLVFSSYPGTIFSGDDFYILGSGLVTLETTIGNKN PALWKYVQPQGCVLEWIRNVVANRLALDGATWADVFKRFNSGTYNSQWMIVDYKAFL PNGPSPGSRVLTILEQIPGMVVVADKTAELYKTTYWASYNIPYFETVFNASGLQALVA QYGDWFSYTKNPRAKIFQRDQSLVEDMDAMVRLMRYNDFLHDPLSLCEACNPKPNAEN AISARSDLNPANGSYPFQALHQRAHGGIDVKVTSFTLAKYMSMLAASGPTWDQCPPFQ WSKSPFHSMLHMGQPDLWMFSPIRVPWD” BASE COUNT 675 a 1133 c 945 g 816 t ORIGIN 1 acctgccctc gcgatggcgg cccccgtgga tgggagctcc ggcggctggg cggcccgggc 61 gctacggcgg gcactggcgc tgacctccct gaccacactg gccttgctgg cctcgctgac 121 cgggctgttg ctgagcggcc cggcgggcgc tctccctacc ctggggcccg gctggcagcg 181 ccaaaatccg gacccgccgg tctcccgcac ccgctcgctg ctgctggacg ccgcgtcggg 241 ccagctgcgc ctggaggatg gcttccaccc cgacgcggtg gcctgggcca acctcaccaa 301 cgccatccgc gagaccgggt gggcctatct ggacctgagc acaaatggca ggtacaatga 361 cagcctgcag gcctatgcag ctggtgtggt ggaggcctct gtgtctgagg agctcatcta 421 catgcactgg atgaacacgg tggtcaacta ctgcggcccc ttcgaatacg aagtcggcta 481 ctgtgagaag cttaagaact tcctggaggc caacctggag tggatgcaga gggaaatgga 541 gcttaacccg gactctccgt actggcacca ggtgcggctg accctcctgc agctgaaagg 601 cctggaggac agctatgaag gccgtttaac cttcccaact gggaggttca ccatcaaacc 661 cttggggttc ctcctgctgc agatctctgg agacctggaa gacctagagc cagccctgaa 721 taagaccaac accaagcctt ccctgggctc cggttcatgc tctgccctca tcaagctgct 781 gcctggcggg catgacctcc tggtggcgca caacacgtgg aactcctacc agaacatgtt 841 acgcatcatc aagaagtaca ggctgcagtt ccgggagggg ccgcaagagg agtaccccct 901 ggttgctggc aacaacttgg ttttctcgtc ctacccgggc accatcttct ccggagatga 961 cttctacatc ctgggcagtg gcctggtcac cctggagacc accattggca acaagaaccc 1021 agccctgtgg aagtacgtgc agccccaggg ctgtgtgctg gagtggatac gaaatgtcgt 1081 ggccaaccgc ctggccttgg acggggccac ctgggcagac gtcttcaagc ggttcaacag 1141 cggcacgtac aatagccagt ggatgattgt ggactacaag gcattcctcc ccaacggacc 1201 cagccctgga agccgggtgc tcactatcct agaacagatc ccgggcatgg tggtggtggc 1261 tgacaagact gcagagctct acaaaacgac ctactgggct agctacaaca tcccgtactt 1321 tgagactgta ttcaacgcta gtgggctgca ggccctggtg gcccagtatg gagattggtt 1381 ctcttacact aagaaccctc gagccaagat cttccagagg gaccagtcac tggtggagga 1441 catggacgcc atggtccggc tcatgaggta caatgatttc ctccatgacc ctctgtcatt 1501 gtgtgaagcc tgcaacccaa agcctaatgc ggagaatgcc atctctgccc gctctgacct 1561 caaccccgcc aatggctcct acccatttca ggccctgcat cagcgcgccc atggtggcat 1621 tgatgtgaag gtgaccagct ttaccctggc caagtacatg agcatgctgg cggccagtgg 1681 ccccacgtgg gaccagtgtc ctccgttcca gtggagcaaa tcgccattcc acagcatgct 1741 gcacatgggc cagcccgacc tctggatgtt ctcacccatc agggtgccat gggactgaga 1801 gagagtccgc ctccgcctag ctgccttcat tttgtgtggc cagtgggtca tacacctgcc 1861 gtccacccct cgggcttctg tcttcactag actctggtcc tagcggcttc cttcgcaagg 1921 acacaaccca gtgggctcag agttgcctct gtccctgagc cctctgcccc ttcatggctc 1981 atcctccctg tccctgtcac cagcaggctg gggcttatgc ttggctgtgg gcctggtggg 2041 atccggggca cacattctcc tagtgctggt ccctcagcat atgtgtgaac tgacagggga 2101 cattatggtt gtcactgctg gcctgtgggc ccatcgcctc agaaggcagc cctgtgccct 2161 tctgggcagc tcttctaagt gcaggagctt gagaacaaaa ccaaagtttc tggctgcttg 2221 tagctggagg gccttgagtc ttctttcagc aggaggaatg gaccgtcacc ccacacttct 2281 acccctactc ccagccaagc ctgcccctgg cctcctggta ggtgtctctg gctgtgtgct 2341 ccggtcagcg aagcccaggc tgtgcttctg ttaaacaagc cttgtggggc ggcaccacac 2401 cctgtctgtc catggctgtc tccttccatc tgtcctttct ctagtccacg tacctactgt 2461 tcacctgcat caccagcccc ctgcccgtcc atcccctctc ctgtccaccc taccgtcttt 2521 tcactcagtc agcggtccac acacctaccc gtccacttgc ctgccttttc atctgaacgt 2581 cctcacctct cacccaccca tccacctgcc cgtccgtcag tctgtccacc cagaactgca 2641 catccctttt cattttggtt ttgctctgta actcagtgtg gccttgaact tgaatgcctt 2701 gtggtccaca gtcatcctct ggttattgta tctgctggcc gccttcaccc tcacatgctg 2761 ggtttccatg tacaggccgc cgtgccttga ttctgctttt catcagccca ctcatctctc 2821 tgtccattta tccctgttag tccttctgct cagcatctgt ctcaagtgct gtattctggg 2881 tcctagcctg gcccaacctg ctgaccacta agaccctaaa tcctagaccc agagacccac 2941 atgaaaccaa gtcccctgtg tggggcccag agagctcaca gcctgtgaac cagaggccct 3001 aagatgtgtg ggtagcttta cccgagccag tccgggcctg ccatgtgttc tgagtttcgt 3061 tggtagtcag gggttggttt cctgtcaggt tcactccacc ttccctgctc tgcagatgcc 3121 tgcacggggt tggttttcca gacaccaggg tggggccgct ggtgtctcag gatggccttg 3181 tcctgtccct aaggacttca tattagcatg tggtggcctt gcctgtgcat ctcccagctg 3241 ctttgtgacc ccaccctaga tccctgtgtg gcttagctct ggtcctctct cctgacttac 3301 ggatgtgtgg gttccaccag tcaatccact gggagaccca agaccccaga ggggagcacc 3361 actcctttga gagccaggga cgatgtggct gggtgtaaag ggagactgaa caaggcaagg 3421 aagctaacgc ctgtctgccc ggcactcaga agatgaggca ggaggatctc cagtttgaga 3481 ccagcctggg ctgcacatag accctcatgt caagaacaaa caaagctcaa aagatctttg 3541 ctctataaat atatatttat tttttattt // (SEQ ID 3) LOCUS AF261233  2868 bp mRNA linear ROD 25-JUN-2002 DEFINITION Mus musculus sodium/calcium exchanger protein mRNA, complete cds. ACCESSION AF261233 /translation = “MASRWLALLWAPVFLCVALLLETASGTGDPSTKAHGHIQFSAGS VNQTAMADCRAVCGLNTSDRCDFVRRNPDCRSEAGYLDYLEGIFCYFPPNLLPLAITL YVFWLLYLFLILGVTAAKFFCPNLSAISTNLKLSHNVAGVTFLAFGNGAPDIFSALVA FSDPRTAGLAIGALFGAGVLVTTVVAGGITILHPFMAASRPFLRDIAFYMVAVFLTFT ALYLGRITLAWALGYLGLYVFYVVTVIICTWVYQRQRSRSLVHSISETPELLSESEED QMSSNTNSYDYGDEYRPLLLGQETTVQILIQALNPLDYRKWRTQSISWRVLKVVKLPV EFLLLLTVPVVDPDKDDRNWKRPLNCLQLVISPLVLVLTLQSGVYGLYEIGGLLPVWA VVVIVGTALASVTFFATSNREPPRLHWLFAFLGFLTSALWINAAATEVVNILRSLGVI LRLSNTVLGLTLLAWGNSIGDAFSDFTLARQGYPRMAFSACFGGIIFNILVGVGLGCL LQIIRNHVVEVKLEPDGLLVWVLASALGLSLIFSLVSVPLQCFQLSKAYGLCLLLFYV CFLVVVLLTEFGVIHLKKA” BASE COUNT 505 a 800 c 829 g 734 t ORIGIN 1 ctccgggcca ggactctagg ggcggaaggt tgtggcgctg gccatccggc tagaggaaga 61 ctccgaggtc gcggatccag gccccgcccg aggcactaga gcagccagcc cgtgagcaga 121 gagggctctg gtcaggcctc aaggggccca tggcaagcag atggctggct ctgctctggg 181 ctcctgtctt cctctgtgtg gctctgttac tggagacggc gtctgggacc ggagacccat 241 ccacaaaagc ccatggacac atccagtttt cagctggaag tgtcaaccag actgccatgg 301 cggattgccg agccgtgtgt ggcctgaaca catctgatcg ctgtgacttt gtcaggagga 361 atccggactg ccgcagcgag gcgggctacc tggactacct tgagggcatc ttctgctact 421 tcccccccaa cctcctccct ctggccatca ccctctacgt tttctggctg ctttacctct 481 ttctgatcct gggagtcacc gcggccaagt tcttctgccc taacctgtca gccatctcca 541 ctaacctcaa actctcccac aacgtggcag gtgtcacctt cctggccttt ggaaatggcg 601 ctccagacat cttcagtgct ttagtggctt tctcagaccc acgtactgcc ggcctggcca 661 tcggggctct gtttggtgca ggggtgctgg tcaccactgt ggtggctgga ggcatcacca 721 tcctgcatcc cttcatggct gcctccaggc ccttcctcag ggacatcgct ttctacatgg 781 tggctgtgtt cctaaccttc actgcactct atcttggcag gatcacgctg gcgtgggcgc 841 tgggttacct gggcctctac gtgttctacg tggtcacggt catcatctgc acttgggtct 901 accaacggca gcgaagcagg tctctggtcc actccatatc ggagacacca gagttgctgt 961 ctgagtcaga ggaggaccag atgtcttcca acaccaacag ctatgactat ggagatgagt 1021 accggcctct gttgctgggt caggagacca ctgtccagat cctgatccaa gccctgaatc 1081 ccttggacta caggaagtgg agaactcagt cgatatcctg gagggtcctg aaggtagtca 1141 agttacctgt ggagttcttg ttgctgctca cagtaccggt tgtggaccct gacaaggacg 1201 atcggaattg gaaacggcca ctcaactgtc tgcagctggt catcagcccc ctggtcctgg 1261 tcctgaccct gcagtcgggg gtctatggcc tctatgagat tggcggtctc cttcctgtct 1321 gggctgtggt ggtgatcgtg ggcacagcgc tggcttcagt gaccttcttt gccacgtcta 1381 acagagaacc ccctagactg cactggctct ttgctttcct gggtttcctg accagtgccc 1441 tgtggatcaa tgcagccgcc acagaggtgg tgaacatctt acggtccctg ggtgtgatcc 1501 tccgcctgag caacaccgtc ctagggctga ccctcctggc ctggggaaac agcattggag 1561 atgccttctc agatttcacg ctggcccgcc aaggataccc tcggatggcc ttctccgcct 1621 gtttcggggg catcatcttc aacatcctgg ttggtgtggg gctgggctgc ttgctgcaga 1681 tcatcaggaa ccacgttgtg gaggtgaagc tggagccaga cggattactg gtgtgggtgc 1741 tggccagtgc cctgggcctc agcttgatct tctccctggt ctccgtgccg cttcagtgtt 1801 tccagctcag caaggcttac ggcctctgcc tcctcctctt ctacgtctgt ttccttgttg 1861 tggtcctgct cacagagttt ggggtgattc acctgaagaa ggcgtgactg aagctgcttg 1921 gcctagaggt gtgggggcga ttctgctagc ctcctgaggg ggaggtgtgg ggagggggac 1981 cctctgtggt ccccgtggat ctcctgagaa gatagtcact ggcagagctc tgcagggtga 2041 gaaggtcctg actgccggca cctaacagcc ttagtgtggg gatctggagg ctggctttgc 2101 tggggacaat cccgggtagg aatgatggga tctaaatgac accggaggct ctggggggag 2161 ggcagccttt cagtcagccc ccatgcctgc tgggctctgg gcagccctgc agttccctct 2221 ctggctcttc cactctctgt ggggtcctgc gtacctacag ggtggcctga aaacagactc 2281 cacacgtgga aacaagactg ggtttctcag cttccgtgtc aagtcagcca gaggaaagag 2341 gtcgagttga cagcagcagg cactgccctt cctagttggt ggctgccatg ttggactgtg 2401 gatctaaaac acttctagag ctttgtggtc caaactctgg ctctcccgtc tgcaaaacag 2461 gagccagcat gggctctgtg cctacctcaa ggggagctgg gggttggggg gactgaccct 2521 ccccagggag gtcttacaag tagtgtgacc agtcttttgt ttgtttggtt ggttggttgt 2581 tttttggaga cagggtttct ctgtgtagcc ctggctgtcc tggaactcac tctgtagacc 2641 aggctggcct tgaactcaga aatctgcctg cctttgcctc ccaagtgctg ggactaaagg 2701 tgtgtgccac cactgtccag cttgtgacca gccttttaaa agtgccactc actccctgac 2761 tgccttcagc tgtaattaag agacttgact gttggggttt ttttttgttt gtttgttttt 2821 tgtttttgtt ttttgttgtt tccaaaaata aaagatgagt tatttcac // (SEQ ID 4) LOCUS AF319547  3324 bp mRNA linear ROD 25-JUN-2002 DEFINITION Mus musculus ATP-dependent RNA-helicase (Ddx) mRNA, Ddx-RV allele, complete cds. ACCESSION AF319547 /translation = “MAAGRRVGPGPPSRPTMAPWKKKRLRKRRTGASQGRDSDSDDGE FEIQAEDDARARKLGPGRALPSFPTSECVSDVEPDTREMVRAQNKKKKKSGGFQSMGL SYPVFKGIMKKGYKVPTPIQRKTIPVILDGKDVVAMARTGSGKTACFLLPMFERLKAR SAQTGARALILSPTRELALQTMKFTKELGKFTGLKTALILGGDKMEDQFAALHENPDI IIATPGRLVHVAVEMNLKLQSVEYVVFDEADRLFEMGFAEQLQEIIGRLPGGHQTVLF SATLPKLLVEFARAGLTEPVLIRLDVDSKLNEQLKTSFLLVREDTKAAVLLYLLQNVV RPQDQTVVFVATKHHAEYLTELLMGQGVSCAHIYSALDQTARKINLAKFTHNKCSTLI VTDLAARGLDIPLLDNVINYSFPAKGKLFLHRVGRVARAGRSGTAYSLVAPDEVPYLL DLHLFLGRSVTLARPCEEPSVADAVGRDGVLGRVPQSVVDDEDSSLQTAMGASLDLQG LHRVANNAQQQYVRSRPAPSPESIKRAKELDLAELGLHPLFSSCFEEGELQRLRLVDS IKNYRTRTTIFEINASSKDPSSQMMRAKRQRDRKAVASFQQRRQERQEGPADPAPQR ELPQEEEEEMVETVEGVFTEVVGQKRPRPGPSQGAKRRRMETRQRDQEFYVPYRPK DFDSERGLSVSGAGGAFEQQVAGAVLDLMGDEAQNMSRGQQQLKWDRKKKRFVG QSGQEDK KKIKTESGRFISSSYKRDLYQKWKQKQKIDDRDSEEEGPSNQRGPGPRRGGKRGRSQG TSQPRASSVPAGRMRSELKTKEQILKQRRQAQKQRFLQRGGLKQLSARNRRRAQELRQ GAFGRGAPSRKGKMRKRM” polyA_signal 3303 . . . 3308 /gene = “Ddx” BASE COUNT 725 a 973 c 1023 g 603 t ORIGIN 1 agttaccaca tctctcacag cttggcattc gcgcagttag taggtccctt aagcatctat 61 cacggttcag ttgacacatt ccgcccccac cagttggtat gtccctcagg cctcgcctct 121 gcccggctgg tacaccactt aggccccgcc cccgttctgt tggttcctcc ttctggcttc 181 gcccattgat aaagccatgt tgacgctccg cccctgcgaa gttggttggt ttcctcaggc 241 ccggccccgc cctacgggtg aaacctggat tctcgacgcc gctcttgcgt ctcacaggct 301 ccgcccccgc gcagtcgacg cgtcccttag gccccgccct cttccgggtc taagagcccg 361 gcccgcatgg ctgctggcag acgtgtggga cctggcccgc cgtcgcgtcc caccatggcg 421 ccgtggaaga agaagaggct gcggaaacgc cgaactgggg cttcccaagg ccgcgacagc 481 gactcggatg acggcgagtt cgagatccag gcggaggatg acgcccgggc gaggaagctg 541 ggccctggca gagccttgcc ctcatttcct acctcagagt gcgtatcaga tgtggagccc 601 gacactcggg agatggtgcg agcccagaac aagaaaaaga agaagtctgg aggcttccag 661 tccatgggcc tgagttaccc tgtgttcaag gggatcatga aaaagggcta caaggtgccg 721 acgcccatcc agaggaagac catccccgtg atcttggatg gcaaggatgt ggtggccatg 781 gcccggacag gcagtggcaa gacggcctgc ttcctcctcc cgatgtttga gcggctgaag 841 gcacgcagtg cacagacggg ggctcgagcc ctcatcctct cacccacccg ggagctggcc 901 ctgcagacca tgaagttcac taaagagcta ggcaagttca ccggcctcaa gactgccttg 961 atcctgggtg gagacaaaat ggaagaccag tttgcagccc tgcacgagaa ccctgacata 1021 atcattgcca cccctgggcg tctggtgcat gtggctgtgg agatgaactt gaagctgcag 1081 agtgtggagt atgtggtgtt cgatgaagca gacaggctct ttgaaatggg ctttgctgag 1141 cagctacagg agatcatagg ccgccttcct gggggccacc agacggtgct gttctcagct 1201 acactgccca agctgctggt ggaatttgca cgggcaggcc tcacagagcc cgtgctcatc 1261 cgcctggacg tagactccaa gctcaatgag cagctcaaga cctccttcct ccttgtgcgc 1321 gaagacacca aggctgccgt gctcctctac ctgctgcaga atgtcgttcg gccccaggac 1381 cagactgtgg tgtttgtagc cacaaagcac catgcggagt acctcacaga gttgctgatg 1441 ggccagggtg tgagttgcgc ccacatctat agtgccttgg accagacggc ccgcaagatc 1501 aacttggcca agttcacaca caacaaatgt tccaccctca tcgtgactga cctggccgcc 1561 cggggcctgg acatcccact gctggacaac gtcatcaact acagcttccc tgccaagggc 1621 aagctcttcc tgcaccgagt gggccgtgtg gcccgagcag gccgaagtgg cacagcctat 1681 tctttggtgg ccccagacga ggtcccctac ctgcttgacc tacacctgtt cctgggccgc 1741 tctgtcaccc tggcccgtcc ttgtgaggag ccttcagtgg cagatgcggt tggcagggac 1801 ggagtgctgg gtcgcgtgcc ccagagtgta gtggatgatg aggacagcag cctgcagact 1861 gccatggggg catccctgga tcttcagggc ctgcaccgcg tggccaacaa cgctcagcag 1921 cagtatgtgc gctcacggcc agcgccctcg cctgagtcca tcaagagagc caaggagctg 1981 gacctggcag agctgggctt gcacccactc ttcagctcat gctttgagga gggagagctc 2041 caacgcctga ggctggtgga cagcatcaag aactatcgca cgcgcacaac catctttgag 2101 atcaatgcct ccagcaagga cccaagcagc caaatgatgc gtgccaagcg gcagagggac 2161 cggaaagctg ttgccagttt ccagcagcgg cgccaggaaa ggcaggaagg cccagctgac 2221 ccagcccccc agagggagct gcctcaggag gaggaggagg agatggttga gactgtagag 2281 ggtgtcttca cagaagtcgt gggccagaaa cggccaaggc cgggacccag ccaaggagcc 2341 aagaggcgga ggatggagac ccgtcagcga gaccaggagt tttatgtccc ctaccggccc 2401 aaggatttcg acagtgagcg ggggctgagt gtcagtgggg ctggaggggc ctttgagcag 2461 caggtggctg gtgcagtcct ggacctgatg ggggatgaag cacagaacat gagccggggg 2521 cagcagcagc tcaagtggga ccggaagaag aagcggtttg tggggcagtc aggccaagaa 2581 gacaagaaaa agatcaagac agagagcggc cggtttatca gcagctctta caagcgggat 2641 ctctaccaga agtggaagca gaagcagaaa attgatgacc gggactccga ggaagaaggg 2701 ccatccaacc agcgaggccc tgggccccgc agaggtggaa agcgaggtcg tagtcaaggc 2761 acatcccagc cccgagcttc cagtgtaccc gcaggccgca tgcgctcgga actcaagacc 2821 aaggagcaaa tcctcaagca gcgccggcaa gctcagaagc agcgcttcct gcagcgaggg 2881 ggcctgaagc agctttcagc acgcaaccga cgccgagccc aggagctgcg ccagggcgcc 2941 tttggccggg gtgctccctc caggaagggc aagatgagga aaaggatgtg aggagccaga 3001 cgcagccctg gggcttcctg gtagccccgg gtgtggacgt cagggactat gtccatgtgc 3061 tgttggaaga tccttccaca ggcgctgctc tgtgaggagt agtgccatat ggccacagag 3121 caacagctgc ttttgactgg gacattgggt gacctctgaa aggatgcata ggagtctagc 3181 tatgcaaagc aggcagaccc aagtcctgac cctgcaagtc acagcggctt ctggttccac 3241 accttcagga ttcagagtca gggccgtgtg gatgcctctg acccagcatt gagttttaat 3301 gtaataaact ttactgcctc tagt // (SEQ ID 5) LOCUS AF328926  1858 bp mRNA linear ROD 25-JUN-2002 DEFINITION Mus musculus 2′-5′ oligoadenylate synthetase 1B (Oas1b) mRNA, complete cds. ACCESSION AF328926 /translation = “MEQDLRSIPASKLDKFIENHLPDTSFCADLREVIDALCALLKDR SFRGPVRRMRASKGVKGKGTTLKGRSDADLVVFLNNLTSFEDQLNQQGVLIKEIKKQL CEVQHERRCGVKFEVHSLRSPNSRALSFKLSAPDLLKEVKFDVLPAYDLLDHLNILKK PNQQFYANLISGRTPPGKEGKLSICFMGLRKYFLNCRPTKLKRLIRLVTHWYQLCKEK LGDPLPPQYALELLTVYAWEYGSRVTKFNTAQGFRTVLELVTKYKQLRIYWTVYYDFR HQEVSEYLHQQLKKDRPVILDPADPTRNIAGLNPKDWRRLAGEAATWLQYPCFKYRDG SPVCSWEVPTEVGVPMKYLFCRIFWLLFWSLFHFIFGKTSSG” BASE COUNT 430 a 475 c 501 g 452 t ORIGIN 1 ctgcttcagc gagcctagga gacacaggac ctgctggctg cagaggtatt agctggacct 61 aggatggagc aggatctgag gagcatcccg gcctcgaagc ttgataagtt catagagaac 121 catctcccgg acaccagctt ctgtgctgac ctcagagaag tcatagatgc cctgtgtgct 181 ctcctgaagg acagatcctt ccggggcccc gtccgccgaa tgagggcctc taaaggggtc 241 aagggcaaag gcaccacact caagggcagg tcagacgctg acctggtggt gttccttaac 301 aatctcacca gctttgagga tcagttaaac caacagggag tgttgattaa ggaaattaag 361 aaacagctgt gcgaggttca gcatgagaga cgttgtggag tgaagtttga ggtccacagt 421 ttaaggagtc ccaactcccg ggctctgagc ttcaagctga gcgcccccga cctgctgaag 481 gaggtgaagt ttgatgtgct gccagcctat gatttactgg atcatcttaa catcctcaag 541 aagcctaacc aacaattcta cgccaatctc atcagtgggc gtaccccgcc ggggaaggag 601 ggcaagttat cgatctgctt tatggggctt cggaagtact tcctgaactg tcgcccaacc 661 aagctgaagc gcctcatccg cctggtcacg cactggtacc aactgtgtaa ggagaagctg 721 ggggacccgc tgcccccaca gtatgccctg gagctgctca cagtctatgc ctgggagtat 781 gggagtcgag taactaaatt caacacagcc cagggcttcc gaaccgtctt ggaactggtc 841 accaagtaca aacagcttcg aatctactgg acagtgtatt atgactttcg acatcaagag 901 gtctctgaat acctgcacca acagctcaaa aaagacaggc ctgtgatctt ggaccccgct 961 gacccaacaa ggaacatagc tggtttgaac ccaaaggact ggcggcgtct agcaggagag 1021 gctgccacct ggctgcaata cccatgcttt aagtacaggg acggttcccc agtgtgctcc 1081 tgggaggtgc cgacggaggt tggagtgcca atgaagtatc tcttttgtcg tattttctgg 1141 ttattgtttt ggtctttgtt tcatttcatc tttgggaaga cttcatctgg atagcccaga 1201 gtgtcttgga tattgccatc ctcctgcctt agcgctggca tgactgcagc gtaggcctgt 1261 tatgctctgc ctcccctcca tcctcaagtg gacaagaact gggcatgtgt tttcctgtga 1321 gcccagtggg acctgtccag gaggctccag agtcaggggc atgtcctgct ctgctacagg 1381 gccttgaccc agagaagaca ggaaggtgcc caaagcccaa gagagggagg gtccaacctg 1441 tgatcagact ccaggcttct gtcccctgtc ctcaacccct gcacagacag cctttctcac 1501 agcatgcttt atctgtcttg tcccccaaca gtgttctctg ggagacaaga gattcagaag 1561 gagaatatga tggtttgtat atggttggcc cagggaatgg cactgttagg agatgtggcc 1621 atgttggaat gggtgtggcc ttgtgggtgt gggctttctc ttgtcttagc tgcctggaag 1681 tcagtatgct gctagcagcc ttcaaatgaa gatgtagaac tctcagctcc tcctgcacca 1741 tgcctgcctg gacgttgcca tgctcttgcc ttggtgataa tggactgaac ttctgaacct 1801 gtaagccaac cccaattaaa tgttgttttt ataaaaattg ccttggtcat ggtgtctg // (SEQ ID 6) LOCUS AF328927  1482 bp mRNA linear ROD 25-JUN-2002 DEFINITION Mus musculus serine dehydratase (Sds) mRNA, complete cds. ACCESSION AF328927 /translation = “MEGALAERVGAEPFHRVTPLLESWALSQVAGMPVFLKYENVQIA GSFKIRGIGHFCQQMAKRGCRHLVCSSGGNAGIAAAYSARKLGIPVTIVLPEGTSVQV VRRLEGEGAEVQLTGKVWDEANVKAQELATRDGWVNVSPFDHPLIWEGHASLVRELKE SLGTPPGAVVLAVGGGGLLAGVTAGLLEVGWQHVPIVAMETRGAHSFNSALQAGRPVT LPDITSVAKSLGAKTVAARTLECAKECEVLSEVVEDREAVSAVQRFLDDERMLVEPAC GAALAAIYSGILWRLQAEGRLSSALASVVVIVCGGNNISSQQLQELKTSWAALKISGT PPKFLDTWWVIKGPRFQWSCPLPSR” polyA_signal 1451 . . . 1456 /gene = “Sds” BASE COUNT 296 a 396 c 487 g 303 t ORIGIN 1 gaagaccttg acagaaaacc tcacacccca agggcacatg cagaagaggc cttcctgatt 61 ctgtctcacg tggcttcgtt cttagatgag cccaggtcgt tcatgagcca tgagctgcgt 121 aaggaagaca gagaggattg aataccccca cgggttcatc ttggtcattt tttgttgtga 181 gttctcacca ggaccccaga atcaggagct gtccctttaa caaggaggag gggccaggcc 241 ctggtagccg gaagctgatc tggtagccag tgcgtccagg ttggtcctgg ctgggctgtc 301 cttcaggaag gtggtcagcg cgctgctgga atggaggggg ccttggcaga acgcgtcggg 361 gcggagcctt tccacagggt cacgcccctg ctggagagct gggcgctgtc tcaggtggca 421 ggcatgccgg tcttcctcaa atatgagaat gtgcagatag ctggctcctt taagattcgg 481 ggcatcggac atttctgcca gcagatggcc aagaggggat gcagacatct ggtgtgctcc 541 tcagggggca atgcgggcat tgcggctgca tactcggctc gtaagctggg catccccgtc 601 accatcgtgc tcccagaggg cacctccgtg caggtggtga ggcggctcga gggggaaggg 661 gccgaggtcc agctgactgg gaaagtctgg gatgaagcca atgtaaaagc acaagaactg 721 gccacaaggg atggctgggt gaacgtctcc ccgtttgacc atccccttat atgggaaggc 781 catgccagcc tagtgcggga gctgaaggag tcactaggga cccctccagg tgccgtggtg 841 ctggccgtgg ggggcggagg gctcctggca ggtgtgactg ctggcctgct ggaggtgggc 901 tggcagcatg tgcccatcgt tgccatggag acccgcgggg cgcacagttt caattcggcc 961 ttgcaggcag gcaggccggt caccctgcca gacatcacca gtgtagccaa gagcctcgga 1021 gccaagacgg tggctgcacg gaccttggag tgtgcaaagg agtgtgaggt cctctctgag 1081 gtggtagaag accgggaggc tgtcagcgct gtgcagaggt tcctggacga tgagcgcatg 1141 ctggtggaac ctgcctgcgg tgccgccctg gccgccatct actcgggcat cctgtggagg 1201 cttcaggctg agggccgcct gagttctgcc ctagcttccg ttgtggtcat cgtgtgcggt 1261 ggcaacaaca ttagtagcca acagcttcag gagctgaaaa ccagctgggc tgcattgaaa 1321 atctcaggaa ctcccccaaa gttcctggac acctggtggg tcatcaaggg acctcggttc 1381 cagtggtcct gccctcttcc ttccaggtag ccctcctggg ttgctctcag tggctccctg 1441 ctgtccagtg aataaacctg actgagctga aaaaaaaaaa aa // (SEQ ID 7) LOCUS AF418004  1837 bp mRNA linear ROD 25-JUN-2002 DEFINITION Mus musculus C3H/He 2′-5′ oligoadenylate synthetase 1B (Oas1b) mRNA, complete cds. ACCESSION AF418004 /translation = “MEQDLRSIPASKLDKFIENHLPDTSFCADLREVIDALCALLKDR SFRGPVRRMRASKGVKGKGTALKGRSDADLVVFLNNLTSFEDQLNQQGVLIKEIKKQL CEVQHERRCGVKFEVHSLRSPNSRALSFKLSAPDLLKEVKFDVLPAYDLLDHLNILKK PNQQFYANLISGRTPPGKEGKLSICFMGLQKYFLNCRPTKLKRLIRLVTHWYQLCKEK LGDPLPPQYALELLTVYAWEYGSRVTKFNTAQGF” BASE COUNT 428 a 476 c 491 g 442 t ORIGIN 1 ctgcttcagc cagcctagga gacacaggac ctgctggctg cagaggtaaa agctggacct 61 aggatggagc aggatctgag gagcatcccg gcctcgaagc ttgataagtt catagagaac 121 catctcccgg acaccagctt ctgtgctgac ctcagagaag tcatagatgc cctgtgtgct 181 ctcctgaagg acagatcctt ccggggcccc gtccgccgaa tgagggcctc taaaggggtc 241 aagggcaaag gcaccgcgct caagggcagg tcagacgctg acctggtggt gttccttaac 301 aatctcacca gctttgagga tcagttaaac caacagggag tgttgattaa ggaaattaag 361 aaacagctgt gcgaggttca gcatgagaga cgttgtggag tgaagtttga ggtccacagt 421 ttaaggagtc ccaactcccg ggctctgagc ttcaagctga gcgcccccga cctgctgaag 481 gaggtgaagt ttgatgtgct gccagcctat gatttactgg atcatcttaa catcctcaag 541 aagcctaacc aacaattcta cgccaatctc atcagtgggc gtaccccgcc ggggaaggag 601 ggcaagttat cgatctgctt tatggggctt cagaagtact tcctgaactg tcgcccaacc 661 aagctgaagc gcctcatccg cctggtcacg cactggtacc aactgtgtaa ggagaagctg 721 ggggacccgc tgcccccaca gtatgccctg gagctgctca cagtctatgc ctgggagtat 781 gggagtcgag taactaaatt caacacagcc cagggcttct gaaccgtctt ggaactggtc 841 accaagtaca aacagcttca aatctactgg acagtgtatt atgactttcg acatcaagag 901 gtctctgaat acctgcacca acagctcaaa aaagacaggc ctgtgatctt ggaccccact 961 gacccaacaa ggaacatagc cggtttgaac ccaaaggact ggaggcgtct agcaggagag 1021 gctgccgcct ggctgcaata cccatgcttt aagtacaggg acggttcctc agtgtgctcc 1081 tgggaggtgc cgacggaggt tgcagtgcca acgaagtatc tcttttgtcg tattttctgg 1141 ttattgtttt ggtctttgtt tcatttcatc tttgggaaga cttcatctgg atagcccaga 1201 gtgtcttgga tattgccatc ctcctgcctt agcgctggca tgactgcagc gtaggcctgt 1261 tatgccctgc ctcccttcca tcctcaagtg gacaagaact gggcatgtgt tttcctgtga 1321 gcccagtggg acctgtccag gatgctccag agtcagacgc atgtcctgct ctgctgcagg 1381 gccttgaccc agagaagaca ggaaggtgcc caaagcccaa gagagggagg gtccaacctg 1441 tgatcagact ccaggcttct gtcccctgcc ctcaacccct gcacagacag cctttctcac 1501 agcctgcttt atctgccttg tcccccaaca gtgttctctg ggagacaaga gattcagaag 1561 gagaatatta tggtttgtat atggttggcc cagggaatgg cactgttagg aggtgtggcc 1621 atgttggagt gggtgtggcc ttgtgggtgt gggctttctc ttgtcttagc tgcctggaag 1681 tcagtattct gctagcagcc ttcagatgaa gatgtagaac tctcagctcc tcctgcacca 1741 tgcctgcctg gacgttgcca tgctcttgcc ttggttataa tggactgaac gtctgaacct 1801 gtaagccaac cccaattaaa tgttgttttt ataaaaa // (SEQ ID 8) LOCUS AF418005  1837 bp mRNA linear ROD 25-JUN-2002 DEFINITION Mus musculus BRVR 2′-5′ oligoadenylate synthetase 1B (Oas1b) mRNA, complete cds. ACCESSION AF418005 /translation = “MEQDLRSIPASKLDKFIENHLPDTSFCADLREVIDALCALLKDR SFRGPVRRMRASKGVKGKGTTLKGRSDADLVVFLNNLTSFEDQLNQQGVLIKEIKKQL CEVQHERRCGVKFEVHSLRSPNSRALSFKLSAPDLLKEVKFDVLPAYDLLDHLNILKK PNQQFYANLISGRTPPGKEGKLSICFMGLRKYFLNCRPTKLKRLIRLVTHWYQLCKEK LGDPLPPQYALELLTVYAWEYGSRVTKFNTAQGFRTVLELVTKYKQLRIYWTVYYDFR HQEVSEYLHQQLKKDRPVILDPADPTRNIAGLNPKDWRRLAGEAATWLQYPCFKYRDG SPVCSWEVPTEVGVPMKYLFCRIFWLLFWSLFHFIFGKTSSG” BASE COUNT 431 a 472 c 493 g 441 t ORIGIN 1 ctgcttcagc cagcctagga gacacaggac ctgctggctg cagaggtaaa agctggacct 61 aggatggagc aggatctgag gagcatcccg gcctcgaagc ttgataagtt catagagaac 121 catctcccgg acaccagctt ctgtgctgac ctcagagaag tcatagatgc cctgtgtgct 181 ctcctgaagg acagatcctt ccggggcccc gtccgccgaa tgagggcctc taaaggggtc 241 aagggcaaag gcaccacact caagggcagg tcagacgctg acctggtggt gttccttaac 301 aatctcacca gctttgagga tcagttaaac caacagggag tgttgattaa ggaaattaag 361 aaacagctgt gcgaggttca gcatgagaga cgttgtggag tgaagtttga ggtccacagt 421 ttaaggagtc ccaactcccg ggctctgagc ttcaagctga gcgcccccga cctgctgaag 481 gaggtgaagt ttgatgtgct gccagcctat gatttactgg atcatcttaa catcctcaag 541 aagcctaacc aacaattcta cgccaatctc atcagtgggc gtaccccgcc ggggaaggag 601 ggcaagttat cgatctgctt tatggggctt cggaagtact tcctgaactg tcgcccaacc 661 aagctgaagc gcctcatccg cctggtcacg cactggtacc aactgtgtaa ggagaagctg 721 ggggacccgc tgcccccaca gtatgccctg gagctgctca cagtctatgc ctgggagtat 781 gggagtcgag taactaaatt caacacagcc cagggcttcc gaaccgtctt ggaactggtc 841 accaagtaca aacagcttcg aatctactgg acagtgtatt atgactttcg acatcaagag 901 gtctctgaat acctgcacca acagctcaaa aaagacaggc ctgtgatctt ggaccccgct 961 gacccaacaa ggaacatagc tggtttgaac ccaaaggact ggcggcgtct agcaggagag 1021 gctgccacct ggctgcaata cccatgcttt aagtacaggg acggttcccc agtgtgctcc 1081 tgggaggtgc cgacggaggt tggagtgcca atgaagtatc tcttttgtcg tattttctgg 1141 ttattgtttt ggtctttgtt tcatttcatc tttgggaaga cttcatctgg atagcccaga 1201 gtgtcttgga tattgccatc ctcctgcctt agcgctggca tgactgcagc gtaggcctgt 1261 tatgctctgc ctcccctcca tcctcaagtg gacaagaact gggcatgtgt tttcctgtga 1321 gcccagtggg acctgtccag gaggctccag agtcaggggc atgtcctgct ctgctacagg 1381 gccttgaccc agagaagaca ggaaggtgcc caaagcccaa gagagggagg gtccaacctg 1441 tgatcagact ccaggcttct gtcccctgtc ctcaacccct gcacagacag cctttctcac 1501 agcatgcttt atctgtcttg tcccccaaca gtgttctctg ggagacaaga gattcagaag 1561 gagaatatga tggtttgtat atggttggcc cagggaatgg cactgttagg agatgtggcc 1621 atgttggaat gggtgtggcc ttgtgggtgt gggctttctc ttgtcttagc tgcctggaag 1681 tcagtatgct gctagcagcc ttcaaatgaa gatgtagaac tctcagctcc tcctgcacca 1741 tgcctgcctg gacgttgcca tgctcttgcc ttggtgataa tggactgaac ttctgaacct 1801 gtaagccaac cccaattaaa tgttgttttt ataaaaa // (SEQ ID 9) LOCUS AF418006  1837 bp mRNA linear ROD 25-JUN-2002 DEFINITION Mus musculus MOLD/Rk 2′-5′ oligoadenylate synthetase 1B (Oas1b) mRNA, complete cds. ACCESSION AF418006 translation = “MEQDLRSIPASKLDKFIENHLPDTSLCADLREVIDALCALLKDR FFRGPVRRMRASKGVKGKCTALKGRSDADLVVFLNNLTYFEDQLNQQGVLIKEIKKQL YEVQHERRFGVKFEVQSLRSPNSRALSFKLSAPDLLKEVKFDVLPAYDLLDHLNILKK PNQQFYANLISGRTPLGKEGKLLTCFMGLRKYFLNCRPTKLKRLIRLVTHWYQLCKEK LGDPLPPQYALELLTVYAWEYGSRVTKFNTAQGFRTVLELVTKYKQLRIYWTVYYDFR HQEVSEYLHQQLKKDRPVILDPADPTRNIAGLNPKDWRRLAGEAAAWLQYPCFKYRDG SPVCSWEVPTEVAVPTKYLFCRIFWLLFWSLFHFIFGKTSSG” BASE COUNT 425 a 470 c 491 g 451 t ORIGIN 1 ctgcttcagc cagcctagga gacacaggac ctgctggctg cagaggtaaa agctggacct 61 aggatggagc aggatctgag gagcatcccg gcctcgaagc ttgataagtt catagagaat 121 catctcccgg acaccagctt gtgtgctgac ctcagagaag tcatagatgc cctgtgtgct 181 ctcctgaagg acagattctt ccggggcccc gtccgccgaa tgagggcctc taagggggtc 241 aagggcaaat gcaccgcgct caagggcagg tcagacgctg acctggtggt gttccttaac 301 aatctcacct actttgagga tcaattaaac caacagggag tgttgattaa ggaaattaag 361 aaacagctgt acgaggttca gcatgagaga cgttttggag tcaagtttga ggtccagagt 421 ttaaggagtc ccaactcccg ggctctgagc ttcaagctga gcgcccccga cctgctgaag 481 gaggtgaagt ttgacgtgct gccagcctat gatttactgg atcatcttaa catcctcaag 541 aagcctaacc aacaattcta cgccaatctc atcagtgggc gtaccccgct ggggaaggag 601 ggcaagttat tgacctgctt tatggggctt cggaagtact tcctgaactg tcgcccaacc 661 aagctgaagc gcctcatccg cctggtcacg cactggtacc aactgtgtaa ggagaagctg 721 ggggacccgc tgcccccaca gtatgccctg gagctgctca cagtctatgc ctgggagtat 781 gggagtcgag taactaaatt caacacagcc cagggcttcc gaaccgtctt ggaactggtt 841 accaagtaca aacagcttcg aatctactgg acagtgtatt atgactttcg acatcaagag 901 gtctctgaat acctgcacca acagctcaaa aaagacaggc ctgtgatctt ggaccccgct 961 gatccaacaa ggaatatagc tggtttgaac ccaaaggact ggcggcgtct agcaggagag 1021 gctgccgcct ggctgcaata cccatgcttt aagtacaggg acggttcccc agtgtgctcc 1081 tgggaggtgc cgacggaggt tgcagtgcca acgaagtatc tcttttgtcg tattttctgg 1141 ttattgtttt ggtctttgtt tcatttcatc tttgggaaga cttcatctgg atagcccaga 1201 gtgtcttgga tattgccatc ctcctgcctt agcgctggca tgactgcagt gtaggcctgt 1261 tatgccctgc ctcccctcca tcctcaagtg gacaagaact gggcatgtgt tttcctgtga 1321 gcccagtggg acctgtccag gatgctccag agtcagacgc atgtcctgct ctgctgcagg 1381 gccttgaccc agagaagaca ggaaggtgcc caaagcccaa gagagggagg ttccaacctg 1441 tgatcagact ccaggcttct gtcccctgcc ctcaacccct gcacagacag cctttctcac 1501 agcctgcttt atctgtcttg tcccccaaca gtgttctctg ggagacaaga gattcagaag 1561 gagaatatga tggtttgtat atggttggcc cagggaatgg cactgttagg aggtgtggcc 1621 atgttggagt gggtgtggcc ttgtgtgtgt gggctttctc ttgtcttagc tgcctggaag 1681 tcagtatgct gctagcagcc ttcagatgaa gatgtagaac tctcagctcc tcctgcacca 1741 tgcctgcctg gacgttgcca tgctcttgcc ttggtgataa tggactgaac ttctgaacct 1801 gtaagccaac tccaattaaa tgttgttttt ataaaaa // (SEQ ID 10) LOCUS AF418007  1587 bp mRNA linear ROD 25-JUN-2002 DEFINITION Mus musculus MOLC/Rk 2′-5′ oligoadenylate synthetase 1B (Oas1b) mRNA, complete cds. ACCESSION AF418007   /translation = “MEQDLRSIPASKLDKFIENHLPDTSFCADLREVIDALCALLKDR FFRGPVRRMRASKGVKGKCTALKGRSDADLVVFLNNLTYFEDQLNQQGVLIKEIKKQL YEVQHERRFGVKFEVQSLRSPNSRALSFKLSAPDLLKEVKFDVLPAYDLLDHLNILKK PNQQFYANLISGRTPPGKEGKLLICFMGLRKYFLNCRPTKLKRLIRLVTHWYQLCKEK LGDPLPPQYALELLTVYAWESGSRDCEFNTAQGFRTVLELVTKYKRLRIYWTVYYDFR KTKVSEYLHKLLQKDRPVILDPADPTRNIAGLNPKDWRRLAGEAAAWLQYPCFKYRDG SPVCSWEVPTEVAVPTKYLFCRIFWLLFWSLFHFIFGKTSSG” BASE COUNT 372 a 414 c 428 g 373 t ORIGIN 1 ctgcttcagc cagcctagga gacacaggac ctgctggctg cagaggtaaa agctggacct 61 aggatggagc aggatctgag gagcatcccg gcctcgaagc ttgataagtt catagagaat 121 catctcccgg acaccagctt ctgtgctgac ctcagagaag tcatagatgc cctgtgtgct 181 ctcctgaagg acagattctt ccggggcccc gtccgccgaa tgagggcctc taagggggtc 241 aagggcaaat gcaccgcgct caagggcagg tcagacgctg acctggtggt gttccttaac 301 aatctcacct actttgagga tcaattaaac caacagggag tgttgattaa ggaaattaag 361 aaacagctgt acgaggttca gcatgagaga cgttttggag tcaagtttga ggtccagagt 421 ttaaggagtc ccaactcccg ggctctgagc ttcaagctga gcgcccccga cctgctgaag 481 gaggtgaagt ttgacgtgct gccagcctat gatttactgg atcatcttaa catcctcaag 541 aagcctaacc aacaatttta cgccaatctc atcagtgggc gtaccccgcc ggggaaggag 601 ggcaagttat tgatctgctt tatggggctt cggaagtact tcctgaactg tcgcccaacc 661 aagctgaagc gcctcatccg cctggtcacg cactggtacc aactgtgtaa ggagaagctg 721 ggggacccgc tgcccccaca gtacgccctg gagctgctca cagtgtacgc ctgggaaagt 781 gggagtcgag actgtgaatt caacacagcc cagggcttcc gaactgtctt ggaactggtc 841 accaagtaca agcggcttcg aatctactgg acagtgtatt atgactttag aaagacgaag 901 gtctctgaat acctgcacaa actgctccaa aaagacaggc ctgtgatctt ggaccccgct 961 gatccaacaa ggaatatagc tggtttgaac ccaaaggact ggcggcgtct agcaggagag 1021 gctgccgcct ggctgcaata cccatgcttt aagtacaggg acggttcccc agtgtgctcc 1081 tgggaggtgc cgacggaggt tgcagtgcca acgaagtatc tcttttgtcg tattttctgg 1141 ttattgtttt ggtctttgtt tcatttcatc tttgggaaga cttcatctgg atagcccaga 1201 gtgtcttgga tattgccatc ctcctgcctt agcgctggca tgactgcagt gtaggcctgt 1261 tatgccctgc ctcccctcca tcctcaagtg gacaagaact gggcatgtgt tttcctgtga 1321 gcccagtggg acctgtccag gatgctccag agtcagacgc atgtcctgct ctgctgcagg 1381 gccttgaccc agagaagaca ggaaggtgcc caaagcccaa gagagggagg ttccaacctg 1441 tgatcagact ccaggcttct gtcccctgcc ctcaacccct gcacagacag cctttctcac 1501 agcctgcttt atctgtcttg tcccccaaca gtgttctctg ggagacaaga gattcagaag 1561 gagaatatga tggtttgtat atggttg // (SEQ ID 11) LOCUS AF418008  1587 bp mRNA linear ROD 25-JUN-2002 DEFINITION Mus musculus MOLF/Ei 2′-5′ oligoadenylate synthetase 1B (Oas1b) mRNA, complete cds. ACCESSION AF418008 translation = “MEQDLRSIPASKLDKFIENHLPDTSFCADLREVIDALCALLKDR FFRGPVRRMRASKGVKGKCTALKGRSDADLVVFLNNLTYFEDQLNQQGVLIKEIKXQL YEVQHERRFGVKFEVQSLRSPNSRALSFKLSAPDLLKEVKFDVLPAYDLLDHLSILKK PNRQLYANLISGRTPPGKDPKLSICFMGLRKYFLNCRPTKLKRLIRLVTQWYQLCKEK LGDPLPPQYALELLTVYAWESGSRDCEFNTAQGFRTVLELVTKYKRLRIYWTVYYDFR KTKVSEYLHKLLQKDRPVILDPADPTRNIAGLNPKDWRRLAGEAAAWLQYPCFKYRDG SPVCSWEVPTEVAVPTKYLFCRIFWLLFWSLFHFIFGKTSSG” BASE COUNT 372 a 417 c 427 g 371 t ORIGIN 1 ctgcttcagc cagcctagga gacacaggac ctgctggctg cagaggtaaa agctggacct 61 aggatggagc aggatctgag gagcatcccg gcctcgaagc ttgataagtt catagagaat 121 catctcccgg acaccagctt ctgtgctgac ctcagagaag tcatagatgc cctgtgtgct 181 ctcctgaagg acagattctt ccggggcccc gtccgccgaa tgagggcctc taagggggtc 241 aagggcaaat gcaccgcgct caagggcagg tcagacgctg acctggtggt gttccttaac 301 aatctcacct actttgagga tcaattaaac caacagggag tgttgattaa ggaaattaag 361 aaacagctgt acgaggttca gcatgagaga cgttttggag tcaagtttga ggtccagagt 421 ttaaggagtc ccaactcccg ggctctgagc ttcaagctga gcgcccccga cctgctgaag 481 gaggtgaagt ttgacgtgct gccagcctat gatttactgg atcatcttag catcctcaag 541 aagcctaacc gacaattata cgccaatctc atcagtgggc gtaccccgcc ggggaaggac 601 cccaagttat cgatctgctt tatggggctt cggaagtact tcctgaactg tcgcccaacc 661 aagctgaagc gcctcatccg cctggtcacg caatggtacc aactgtgtaa ggagaagctg 721 ggggacccgc tgcccccaca gtacgccctg gagctgctca cagtgtacgc ctgggaaagt 781 gggagtcgag actgtgaatt caacacagcc cagggcttcc gaactgtctt ggaactggtc 841 accaagtaca agcggcttcg aatctactgg acagtgtatt atgactttag aaagacgaag 901 gtctctgaat acctgcacaa actgctccaa aaagacaggc ctgtgatctt ggaccccgct 961 gatccaacaa ggaatatagc tggtttgaac ccaaaggact ggcggcgtct agcaggagag 1021 gctgccgcct ggctgcaata cccatgcttt aagtacaggg acggttcccc agtgtgctcc 1081 tgggaggtgc cgacggaggt tgcagtgcca acgaagtatc tcttttgtcg tattttctgg 1141 ttattgtttt ggtctttgtt tcatttcatc tttgggaaga cttcatctgg atagcccaga 1201 gtgtcttgga tattgccatc ctcctgcctt agcgctggca tgactgcagt gtaggcctgt 1261 tatgccctgc ctcccctcca tcctcaagtg gacaagaact gggcatgtgt tttcctgtga 1321 gcccagtggg acctgtccag gatgctccag agtcagacgc atgtcctgct ctgctgcagg 1381 gccttgaccc agagaagaca ggaaggtgcc caaagcccaa gagagggagg ttccaacctg 1441 tgatcagact ccaggcttct gtcccctgcc ctcaacccct gcacagacag cctttctcac 1501 agcctgcttt atctgtcttg tcccccaaca gtgttctctg ggagacaaga gattcagaag 1561 gagaatatga tggtttgtat atggttg // (SEQ ID 12) LOCUS AF418009  1587 bp mRNA linear ROD 25-JUN-2002 DEFINITION Mus musculus MOLG/Dn 2′-5′ oligoadenylate synthetase 1B (Oas1b) mRNA, complete cds. ACCESSION AF418009 translation = “MEQDLRSIPASKLDKFIENHLPDTSFCADLREVIDALCALLKDR FFRGPVRRMRASKGVKGKCTALKGRSDADLVVFLNNLTYFEDQLNQQGVLIKEIKKQL YEVQHERRFGVKFEVQSLRSPNSRALSFKLSAPDLLKEVKFDVLPAYDLLDHLNILKK PNQQFYANLISGRTPPGKEGKLSICFMGLRKYFLNCRPTKLKRLIRLVTHWYQLCKEK LGDPLPPQYALELLTVYAWESGSRDCEFNTAQGFRTVLELVTKYKRLRIYWTVYYDFR KTKVSEYLHKLLQKDRPVILDPADPTRNIAGLNPKDWRRLAGEAAAWLQYPCFKYRDG SPVCSWEVPTEVAVPTKYLFCRIFWLLFWSLFHFIFGKTSSG” BASE COUNT 372 a 415 c 428 g 372 t ORIGIN 1 ctgcttcagc cagcctagga gacacaggac ctgctggctg cagaggtaaa agctggacct 61 aggatggagc aggatctgag gagcatcccg gcctcgaagc ttgataagtt catagagaat 121 catctcccgg acaccagctt ctgtgctgac ctcagagaag tcatagatgc cctgtgtgct 181 ctcctgaagg acagattctt ccggggcccc gtccgccgaa tgagggcctc taagggggtc 241 aagggcaaat gcaccgcgct caagggcagg tcagacgctg acctggtggt gttccttaac 301 aatctcacct actttgagga tcaattaaac caacagggag tgttgattaa ggaaattaag 361 aaacagctgt acgaggttca gcatgagaga cgttttggag tcaagtttga ggtccagagt 421 ttaaggagtc ccaactcccg ggctctgagc ttcaagctga gcgcccccga cctgctgaag 481 gaggtgaagt ttgacgtgct gccagcctat gatttactgg atcatcttaa catcctcaag 541 aagcctaacc aacaatttta cgccaatctc atcagtgggc gtaccccgcc ggggaaggag 601 ggcaagttat cgatctgctt tatggggctt cggaagtact tcctgaactg tcgcccaacc 661 aagctgaagc gcctcatccg cctggtcacg cactggtacc aactgtgtaa ggagaagctg 721 ggggacccgc tgcccccaca gtacgccctg gagctgctca cagtgtacgc ctgggaaagt 781 gggagtcgag actgtgaatt caacacagcc cagggcttcc gaactgtctt ggaactggtc 841 accaagtaca agcggcttcg aatctactgg acagtgtatt atgactttag aaagacgaag 901 gtctctgaat acctgcacaa actgctccaa aaagacaggc ctgtgatctt ggaccccgct 961 gatccaacaa ggaatatagc tggtttgaac ccaaaggact ggcggcgtct agcaggagag 1021 gctgccgcct ggctgcaata cccatgcttt aagtacaggg acggttcccc agtgtgctcc 1081 tgggaggtgc cgacggaggt tgcagtgcca acgaagtatc tcttttgtcg tattttctgg 1141 ttattgtttt ggtctttgtt tcatttcatc tttgggaaga cttcatctgg atagcccaga 1201 gtgtcttgga tattgccatc ctcctgcctt agcgctggca tgactgcagt gtaggcctgt 1261 tatgccctgc ctcccctcca tcctcaagtg gacaagaact gggcatgtgt tttcctgtga 1321 gcccagtggg acctgtccag gatgctccag agtcagacgc atgtcctgct ctgctgcagg 1381 gccttgaccc agagaagaca ggaaggtgcc caaagcccaa gagagggagg ttccaacctg 1441 tgatcagact ccaggcttct gtcccctgcc ctcaacccct gcacagacag cctttctcac 1501 agcctgcttt atctgtcttg tcccccaaca gtgttctctg ggagacaaga gattcagaag 1561 gagaatatga tggtttgtat atggttg // (SEQ ID 13) LOCUS AF418010  3897 bp mRNA linear ROD 25-JUN-2002 DEFINITION Mus musculus 2′-5′ oligoadenylate synthetase 2 (Oas2) mRNA, complete cds. ACCESSION AF418010 /translation = “MGNWLTGNWSSDRSSGYSSGWSPGGSSGVPSGPVHKLEKSIQAN LTPNENCLKQIAVSSVPSQKLEGYIQENLKPNRESLKQIDQAVDAIWDLLRSQIPVKE VAKGGSYGRETALRGCSDGTLVLFMDCFQQFQDQIKYQDAYLDVIELWLKIHEKKSVK HEHALVVQVSVPGQRILLQLLPVFNPLRSNENPSSCVYVDLKKSMDQVRASPGEFSDC FTTLQQRFFKKYPRRLKDLILLVKHWYEQCQEKWKTPPPQPLLYALELLTVYAWEQGC QAEDFDMAQGVRTVLRLIQRPTELCVYWTVNYNFEDETVRNILLHQLRSQRPVILDPT DPTNNVGKDDGFWELLTEEAMAWLYSPSLNTESPAPYWDVLPMPLFVTPSHLLNKPIK DFLQPNKLFLKQIKEAVDIICSFLKNVCFLNSDTKVLKTVKGGSTAKGTALKRGSDAD IVVFLSSLESYDSLKTNRSQFVQEIQKQLEEFVQAQEWEVTFEISKWKAPRVLSFTLK SKTLNESVEFDVLPAYDALGQLRSDFTLRPEAYKDLIELCASQDIKEGEFSICFTELQ RNFIQTRPTKLKSLLRLIKHWYKQYERKMKPKASLPPKYALELLTVYAWEQGSGTDDF DIAEGFRTVLDLVIKYRQLCIFWTVNYNFEEEYMRKFLLTQIQKKRPVILDPADPTGD VGGGDRWCWHLLAEEAKEWLSSPCFQVEQKGLVQPWKVPVPRDLKTSDMVGVFTTGGI LWQDQGFLSFV” polyA_signal 3878 . . . 3883 /gene = “Oas2” BASE COUNT 978 a 1030 c 940 g 948 t 1 others ORIGIN 1 gaccagctag caacgatggg aaactggctg actggaaact ggtcatctga caggtcatct 61 ggctattcat ctggctggtc acctggtggg tcttcagggg tgccctccgg gccagtgcac 121 aagttagaaa agtctatcca ggcaaacctc acacccaacg aaaactgtct gaagcagatt 181 gcggtgtcct cggtgccatc gcagaagcta gaagggtata tccaggaaaa cctcaaacct 241 aacagagaat ctctgaagca gatagaccag gccgtggatg ccatctggga cctgctgcgc 301 agtcagatcc ctgtgaagga agtggctaag ggtggctcct atggccggga aacagcccta 361 agaggctgct ccgatggtac ccttgttctc ttcatggact gcttccaaca gttccaggat 421 cagataaaat accaagatgc ataccttgac gtcattgaac tgtggctgaa aatccatgag 481 aagaagtcag taaagcatga acatgccctt gtagtacaag tgtctgtacc agggcagaga 541 atactcctgc aattacttcc agtcttcaat cctctacgct ccaatgagaa tcccagctcc 601 tgtgtctatg tggatctcaa aaaatccatg gatcaagtaa gagcctcacc aggggagttc 661 tcagactgct tcaccacact gcagcagcgg tttttcaaga aatatccccg aagactgaag 721 gatttgatcc tattggtcaa gcactggtat gaacagtgcc aggagaagtg gaaaacaccc 781 ccacctcagc cattgctgta cgcactggaa ctgctcactg tgtatgcctg ggaacagggc 841 tgccaagctg aagacttcga catggcacaa ggcgtcagga ccgtgctgcg acttatccag 901 cggccgacag agctgtgtgt ctactggaca gtcaattaca actttgagga tgagacagtc 961 cggaacatcc ttctgcacca gctcaggtcc caaagaccag tcatcttgga tccaactgac 1021 ccaaccaata atgtgggcaa agatgatggg ttctgggagc tactgacaga ggaagctatg 1081 gcctggctgt actctcccag cctgaatact gagtcacctg caccatattg ggatgttctg 1141 cccatgccac ttttcgtcac tccaagccac ttactgaaca agttcatcaa ggactttctc 1201 cagcccaaca agctcttcct aaagcagatc aaggaagctg ttgacattat atgttccttc 1261 cttaaaaatg tctgcttctt gaattctgac accaaagtcc tgaagaccgt caagggagga 1321 tccactgcca aaggcacagc tctgaagcgg ggatcagatg ctgacattgt tgtgttcctc 1381 tcctcgctgg agagttacga ctctctaaaa accaaccgct cccagttcgt ccaggagatc 1441 cagaagcagt tagaagaatt cgtgcaggcg caggagtggg aggtgacgtt tgagatttca 1501 aaatggaagg ctcccagagt gctgagtttt accttgaaat ccaagactct caatgaaagt 1561 gtcgagttcg atgtccttcc cgcctatgat gcactaggtc aactgcggtc tgacttcacc 1621 ctcaggcccg aagcctacaa ggatctcatt gagctgtgtg catcacagga catcaaagaa 1681 ggagagtttt ctatctgttt tactgagctg cagagaaact tcattcaaac ccggcccacc 1741 aaactgaaga gtctactccg cctgatcaag cactggtaca aacagtatga aaggaagatg 1801 aagccaaaag catctttacc cccaaagtac gccctggagc tgctcaccgt gtatgcctgg 1861 gagcagggca gtggcacaga tgactttgac attgctgaag gcttccggac cgtcctggac 1921 ctggttataa aataccggca gctctgcatc ttctggacag tcaattacaa ctttgaagag 1981 gaatacatgc ggaagttcct actgacccag atccagaaaa agaggcctgt aatcctggat 2041 ccagcagatc ccacaggcga tgtgggagga ggtgaccgct ggtgctggca tcttctagct 2101 gaagaagcga aggagtggct gtcctcccct tgtttccaag tggagcaaaa aggcctggta 2161 cagccttgga aagtgccagt acctagagat ctaaagacaa gtgacatggt gggagtgttc 2221 actacaggag ggatcttgtg gcaggaccag ggctttttgt catttgtcta ggtaatgcag 2281 acccccggaa gctgtggagg tcagatctac cccactgtgg gtggagttac taagtaggag 2341 tccattcagc tctggaagac gcttctggag tgatctggca aagactcaga ctgtgttaga 2401 aaagggagcc tggttcagtc ctctctggca ggctcgcacc tctattcttc cttcttggaa 2461 tcaagacatg ggattatcct tcctcctccc ccagggtctc acagcacagg ccctgctctg 2521 tgtgagtgac ctccttcaga gacacttgcc ccatgcagct cgatgggttc tggttttgtc 2581 tgtattctgt gcagttattt tcctgcctcc tgctctgtta gtctctagtc agcagctcca 2641 gactcaccct gtgtcactaa ggttaaggcc ctccctagcc cttcagcatt gtcaatccca 2701 actagccctc ggagtcttcc attgtgcgtc tttgcctgtc tctttccctg tccctgtgga 2761 tacagagatg taccatccat ccagcagcta gccaactccc ctccctccac ctctgctgtt 2821 aaaacccttt ctcttgggga aatgtaaaca atatctacct ctcttaatgt cccaggacaa 2881 actaagctgc atttctccct tccctgagaa gccaaagctt ccctgattga gcttrgctgc 2941 tcacaggaga ggggttacag gcctttgaag ctggccacac tagaagatct gcacccagct 3001 agatgggtgc agatggcttc cctggggctg cataaagaga acccctcccc tcatctttcc 3061 tcctgtatcc tctagcccct ctcagagatc ctgtgcaatc agggcagaat agcatgcagc 3121 tggttgaaac cacttgctaa ataactcagg tgagggtccc ataaccttcc cagcccacct 3181 cccttccaag agtgaagata acagtcaaca agcccagctg tgatgttcat tgataagcag 3241 gctctggtgg actcctaaag atggtgccag tgtggctcag tgaatagccc tgcataacat 3301 tttacacaca ccaaatgctg gttgatatct cttgctggct gcccagggag ccttcacccc 3361 agggctttaa ctgcacagag acatgaggtc taagcccttc gcatccccaa gtaaggctga 3421 gccttttttc tgcctgtgct tgctctgatg cattgaggat catgcctggc cactgtgcaa 3481 cttttaagca gagccgtgca acatcccagg gagttgactt ctatgtaaac accttcatcc 3541 atttctgatg tatgctttga ggtggctcag gctgggctag cccagcccag acagaaatcc 3601 taggcatgtg attagaggat cagaaccctt ctggcccttc ttcaggggag agatggggct 3661 gaaggtgggg ttcaaatctc atgccgagtg atggaacccg acatccctag gtgctaaggc 3721 cccaccaaat tctctggata aggaagttcc aggaatcttt actgataaac atcccaatgt 3781 atcaacaagg tagactctga cctccatggg acagaagatc ctgggtcagt cccctccctg 3841 gggactctgc agttggctgt tcatttatat gcttcataat aaatggtttc tttgtgt // (SEQ ID 14) LOCUS AF453830  4708 bp mRNA linear ROD 25-JUN-2002 DEFINITION Mus musculus 2′-5′ oligoadenylate synthetase 3 (Oas3) mRNA, complete cds. ACCESSION AF453830 /translation = “MDLFHTPAGALDKLVAHNLHPAPEFTAAVRGALGSLNITLQQHR ARGSQRPRVIRIAKGGAYARGTALRGGTDVELVIFLDCFQSFGDQKTCHSETLGAMRM LLESWGGHPGPGLTFEFSQSKASRILQFRLASADGEHWIDVSLVPAFDVLGQPRSGVK PTPNVYSSLLSSHCQAGEYSACFTEPRKNFVNTRPAKLKNLILLVKHWYHQVQTQAVR ATLPPSYALELLTIFAWEQGCGKDSFSLAQGLRTVLALIQHSKYLCIFWTENYGFEDP AVGEFLRRQLKRPRPVILDPADPTWDVGNGTAWRWDVLAQEAESSFSQQCFKQASGVL VQPWEGPGLPRAGILDLGHPIYQGPNQALEDNKGHLAVQSKERSQKPSNSAPGFPEAA TKIPAMPNPSANKTRKIRKKAAHPKTVQEAALDSISSHVRITQSTASSHMPPDRSSIS TAGSRMSPDLSQIPSKDLDCFIQDHLRPSPQFQQQVKQAIDAILCCLREKSVYKVLRV SKGGSFGRGTDLRGSCDVELVIFYKTLGDFKGQKPHQAEILRDMQAQLRHWCQNPVPG LSLQFIEQKPNALQLQLASTDLSNRVDLSVLPAFDAVGPLKSGTKPQPQVYSSLLSSG CQAGEHAACFAELRRNFINTCPPKLKSLMLLVKHWYRQVVTRYKGGEAAGDAPPPAYA LELLTIFAWEQGCGEQKFSLAEGLRTILRLIQQHQSLCIYWTVNYSVQDPTIRAHLLC QLRKARPLVLDPADPTWNVGQGDWKLLAQEAAALGSQVCLQSGDGTLVPPWDVTPALL HQTLAEDLDKFISEFLQPNRHFLTQVKRAVDTICSFLKENCFRNSTIKVLKVVKGGSS AKGTALQGRSDADLVVFLSCFRQFSEQGSHRAEIISEIQAQLEACQQTHSFDVKFEVS KRKNPRVLSFTLTSQTLLDQSVDFDVLPAFDALGQLRSGSRPDPRVYTDLIHSCSNAG EFSTCFTELQRDFITSRPTKLKSLIRLVKYWYQQCNKTIKGKGSLPPQHGLELLTVYA WEQGGQNPQFNMAEGFRTVLELIVQYRQLCVYWTINYSAEDKTIGDFLKMQLRKPRPV ILDPADPTGNLGHNARWDLLAKEATVYASALCCVDRDGNPIKPWPVKAAV” polyA_signal 4690 . . . 4695 /gene = “Oas3” BASE COUNT 1031 a 1322 c 1248 g 1107 t ORIGIN 1 gaaactctac tgagagtacc ggtcaacatg gacctgttcc acacgccagc cggagctctg 61 gataagctgg tggcccacaa cctgcaccca gcccctgagt tcacagcagc cgtacggggt 121 gctctggggt cgctaaacat caccctacag cagcacagag cccgagggtc acagagacca 181 agagtgataa ggattgccaa gggaggagcc tatgcccggg gcacagctct cagaggtggc 241 accgatgtcg aactcgtcat cttcctcgac tgcttccaga gctttggtga ccagaagacc 301 tgtcactcag agaccctggg tgccatgcga atgttgctgg agtcctgggg gggccacccc 361 gggcctggcc tgacttttga gttttctcag tcaaaggcgt ccaggatctt acagtttcgt 421 ctggcatcgg cagacggaga acactggata gatgttagcc tggtgcctgc ctttgatgtc 481 ctaggacagc cccgctctgg agtcaagccg acacccaacg tgtactcctc cctccttagc 541 agccactgcc aggccgggga gtactcagcc tgcttcactg agccccgaaa gaactttgtg 601 aacactcgcc cagccaagct taagaactta atcctgctgg tcaaacactg gtaccaccag 661 gtgcagacac aggccgtgag ggccacactg ccccccagct acgccctaga gctgcttacc 721 atctttgcct gggagcaggg ctgtgggaag gacagcttca gcctggccca agggctccgg 781 accgtcctgg ccttgatcca acacagcaag tacctctgca ttttctggac ggaaaactat 841 ggcttcgagg accctgcagt tggagagttc ttgcgaaggc agcttaagag acccaggccc 901 gtgatcctgg atccagctga tccaacgtgg gacgtgggca acgggacagc ctggcgctgg 961 gatgtgctgg cccaggaggc tgagtccagc tttagccagc agtgcttcaa gcaggcctca 1021 ggagtccttg tgcagccttg ggaggggccg ggcctgccac gggctgggat cttggatttg 1081 ggccacccaa tctatcaagg gcctaaccag gcccttgaag acaacaaagg ccaccttgct 1141 gttcagtcaa aggaaaggag ccaaaaacct tccaattcag ctccaggatt tccagaagca 1201 gccaccaaga tccctgctat gcccaaccca agtgccaata aaacccgcaa gatccgcaag 1261 aaagcagctc acccaaagac tgtccaggaa gcagcattgg atagtatctc aagtcatgtt 1321 cggatcaccc agagcacagc atcctcacac atgcctcctg accgctctag catctccacc 1381 gctgggtcac ggatgagccc agatctgtca cagatcccca gcaaggatct agactgcttc 1441 atccaggacc accttaggcc gagtccccag ttccagcagc aggtgaagca ggccatcgac 1501 gccatcttgt gctgcctccg ggagaagagt gtatacaaag tcttgagggt cagcaagggc 1561 ggctctttcg gccgtggcac agacctcagg ggcagctgcg atgtggaact tgtcatcttt 1621 tataaaaccc tcggggactt caagggccag aagcctcacc aggcagagat cctgcgtgac 1681 atgcaggccc agctacgaca ctggtgtcag aaccccgtgc ctggactgag cctccagttt 1741 attgaacaga agcccaacgc tctgcaactc cagctggcgt ccaccgacct cagcaaccgg 1801 gtggacctca gtgtgctgcc tgcttttgat gctgtggggc cgctgaagtc cggcaccaaa 1861 cctcagcccc aggtgtactc ctcgctcctc agcagcggct gccaggctgg ggagcacgca 1921 gcctgcttcg cagagcttcg aaggaacttc ataaacactt gccctcccaa acttaagagc 1981 ctgatgctac tggtcaaaca ctggtaccgc caggttgtca ctcgatataa aggaggagag 2041 gcggcaggtg atgctccgcc cccagcctac gccctggagc tcctgaccat ctttgcctgg 2101 gaacaaggct gtggagagca aaagttcagc ctggctgaag gcctgcggac catcctgagg 2161 ctgatccaac agcaccagtc gctttgtatc tactggacgg tcaactacag tgtgcaggac 2221 ccgaccatca gagcacatct tctctgccag cttcggaaag ccaggcctct agtcctggac 2281 cctgcagatc ccacctggaa cgtgggccag ggcgactgga agctattagc tcaggaggca 2341 gctgcccttg ggtcacaagt ctgccttcag agtggggatg ggactctggt gccaccctgg 2401 gatgtgacgc cagccctcct tcaccagacc ctagctgagg acctggacaa attcatcagt 2461 gaattcctcc agcccaaccg ccacttcctg actcaagtga agagagccgt ggacaccata 2521 tgttccttcc tgaaagaaaa ctgcttccgg aactctacca tcaaggtgct caaggtggtc 2581 aagggtgggt cttctgccaa aggcacggct ctacaaggac gctcagatgc cgacctggtg 2641 gtgtttctca gctgcttccg ccagttctct gagcaaggca gccatcgggc agagatcatc 2701 tcggagatcc aggctcagct ggaggcgtgt cagcagacgc acagcttcga tgtcaagttt 2761 gaggtctcca agaggaagaa cccccgagtg ctcagcttca cgctgacatc ccagacgctg 2821 ctggaccaaa gcgtggactt tgacgtcctg ccagcctttg atgctctcgg ccagctgagg 2881 tccggctctc ggcctgatcc ccgggtctac acagacctca tccacagctg cagtaatgca 2941 ggagagttct ctacctgctt cacagagctg cagagggact tcattacctc ccgtcccacc 3001 aaactcaaga gcctgatccg gctggtgaaa tactggtacc aacagtgtaa caagaccatc 3061 aaggggaagg gttccttgcc tccccagcac gggctggagc tcctaactgt gtacgcctgg 3121 gagcaaggtg gccagaatcc ccagttcaac atggcggagg gcttccgcac tgttctggag 3181 ctgattgtcc agtaccggca gctctgcgtc tattggacca tcaactacag cgcagaagac 3241 aagaccatcg gtgacttcct gaagatgcag cttcggaagc ccaggcctgt catcctggac 3301 ccagctgacc cgacaggcaa cctgggccac aacgctcgct gggatctgct tgccaaggag 3361 gctaccgtgt acgcatctgc cctgtgctgc gtggacaggg atggcaatcc catcaagcca 3421 tggccggtaa aggccgctgt gtgaagtcta gagagatcag tggtcaccat tgatagaaag 3481 tgacaccagc cctcagcaag tgatactcag agtatctgag tgtgtgtgtg tgtgtgttgt 3541 atttatctgt atgtgtgtat ttgtggtatg tctgtgtgcc tatatgaggg tgtgtctatg 3601 tgcgtgtctg tgtatctgtg ggtatctata tgtgtctgta tatatgtatg tgtgtgtgtg 3661 tgtgtgtgtg tattcatgta tgtgtgtctg tttgtgtata gtgtgtctat aggtgactct 3721 gtgtgtctgt gtatctgtga gtatctatat gtgtctgtct gtatgtaaat gtgtgtatgt 3781 atgtgtgttc atatgtctgt gtgtgtgtct atatctgtgt atctttgggt atctatatgt 3841 gtctatctat atgtaaatgt atgtatgtac ttatgttcat gtgtatctgt gtgaatgtct 3901 gtgtgtttat gtgtagtgta tctgtaagtg tatctgtatg tctatagatg tattatgtct 3961 ttgtgtgtcg acatgtctgt gtgtatgtat gtttgtatgt gtatgttata tatgtatata 4021 tgcatgtatg tgcttcctca caccatctcc cttctgccca cctgcccacc catagccctc 4081 cctttcttcc cactgtttac ccacctggtg gggcttcatt gacctcaacc atgatcatcc 4141 cggtgtccct gactcccaca ctagacaccc taggaaccag acatctctag atcttctagt 4201 ctgctgttca tctaccatgg gctctgcccc aacttccaca gccccaccca ggagtgcctc 4261 agccctgcca agaagccata ctcctccctg gcatctctct gccccttgag cctgtgtata 4321 tccctctgcc tacagagacc caccagctga ggtccaacta tgttcctgta ctggctggtt 4381 ttgtgtgtca acttgacata ggctggagtt atcagagaaa ggagcttcag ttggggaaat 4441 gcctccatga gatccagctg tggggcattt tctcagttgg tgatcaaaga ggagggccca 4501 ttgtgggtgg tgccatccct gggctggtag tcttgagttc tataagagat caagctgagc 4561 aagccagggg aagcaagcca ataagaaaca tccctccatg gcctctgcat cagctcctgc 4621 ttcctgacct gtttgagttc cagttctgac ttcctttagt gatgaacagc aatgtggaag 4681 tgtaagctga ataaaccctt tcctcccc // (SEQ ID 15) LOCUS AF459815  1914 bp mRNA linear ROD 25-JUN-2002 DEFINITION Mus musculus 2′-5′olygoadenylate synthetase 1c (Oas1c) mRNA, Oas1c-RV allele, complete cds. ACCESSION AF459815 /translation = “MENGLCSIQARELDEFICDYLFPDTTFLTELRADIDSISAFLKE RCFQGAAHPVRVSRVVMGGSYDEHTALKGKSEAKMVLFFNNLTSFEEQLKRRGEFVEE IQKHLCQLQQEKPFKVKFEVQSSEEPNSRSLSFKLSSPELQQEVEFDVQPAYDVLYEL RNNTYAEPQFYNKVYAQLIHECTTLEKEGDFSICFTDLHQNFMRYRAPKLWNLIRLVK HWYQLCKEKLREPLPPQYALELLTVYVWEHSNKNQEKVTTAKNFRTFLELVAYYKNLR IYWTWYYDFRHQEVCAYLCRQLKKARPLILDPADPTRNVAGSDLQAWDLLAKEAQ TWMQSSCFRNCDMSFVPTWDLSPERQECAFQ” BASE COUNT 495 a 486 c 489 g 444 t ORIGIN 1 aaacactcct ggcctcagga tggagaatgg tctctgcagc atccaagcca gggagctgga 61 cgagttcata tgtgattacc tctttcctga caccaccttc cttactgagc tcagagcaga 121 catcgactcc ataagtgctt tcctgaagga gagatgcttc caaggtgccg cccatcctgt 181 gagggtctcc agggttgtga tgggcggctc ctatgatgaa cacactgcac tcaagggcaa 241 gtcagaggcc aaaatggtgt tgttctttaa caatctcacc agctttgagg agcagttaaa 301 gcgacgggga gagttcgttg aggaaattca gaaacacctg tgtcagctgc agcaagagaa 361 accatttaaa gtgaagtttg aagtgcagag ctcagaggag cccaactcca ggtctctgag 421 cttcaagctg agctcccccg agctccagca ggaggtggaa tttgatgtgc agccagccta 481 tgatgtccta tatgaactga gaaacaacac gtatgctgaa ccccaattct acaacaaagt 541 ctacgcccaa ctcatccatg agtgcaccac cctggagaag gagggcgatt tctccatctg 601 cttcaccgac ctccatcaga acttcatgag gtatcgtgcg cccaagctct ggaacctcat 661 ccgtctggtc aagcactggt atcaactgtg taaggagaag ctgagggagc cgctgccccc 721 acagtacgcc ctggagctgc tcactgtcta tgtatgggaa cattcgaata aaaatcaaga 781 aaaagtaacc acagccaaga acttccggac cttcttagaa ctggtcgcct attacaagaa 841 tcttcgaatc tactggacat ggtattatga cttccgacat caagaggtct gtgcctacct 901 gtgcagacag ctcaaaaaag ccaggcctct gatcctggat ccagcagacc caacaaggaa 961 cgtggctggt tcagacttac aggcatggga cctgctggca aaggaggctc agacctggat 1021 gcagtcctct tgctttagaa actgtgatat gtcctttgtg cccacctggg atttgtcgcc 1081 agagagacaa gaatgtgcct tccagtgagc agtgcagcgc ttgctctgaa ggctccagag 1141 tcaggggcat accttcctct gctgcaagac cttgacctag agaggacagg atggtgctaa 1201 aggctccagt gaggggcatc cagcctgtga tcagactcca ggcttctgat ccctgactgc 1261 ccatggatag ccttcctcac aggctgcttc gtctgcctta gcttccaaca gtgttctctg 1321 ggagtcagac tgtgatggac agagaagaac gcaagctcga cttccatctg tccacctgtt 1381 gggaggttct gtccaacagt ggctgattgt catcaacaaa ccacagcaag ccatggggga 1441 gggtgcactc tgagagaagg aacctttaag tacacttgtg tgtctgtgtg tttaaggatg 1501 tggtgtgtcc atatgcaact agaaaccttg agcacgtgtt acaagctcca catgggccca 1561 ggtaattgcc agaaaggggt ggacagagca aaaccaaact gttacacgta ttgatgttgg 1621 gtagcttggg atccttctag atctctgatg caagaaaccc agactagaat ccatggctcc 1681 tgctgtccat tctcctgtga caaaatttta ggccttcccc atcccacaca gaaactgttc 1741 tccaaccaca catgaccctg gagccctggg aatctggcca gcgtgcatcg tggtgcactg 1801 attctgcagc atgcaggctg aggtccacag cagtgtggga aagtaaaact atgtgcaatt 1861 tgtgaccagt gatgacttga aagcttagct gtctgtgtga gggtgagatt tgaa // (SEQ ID 16) LOCUS AF459816  1911 bp mRNA linear ROD 25-JUN-2002 DEFINITION Mus musculus 2′-5′olygoadenylate synthetase 1c (Oas1c) mRNA, Oas1c-He allele, complete cds. ACCESSION AF459816 /translation = “MENGLCSIQARELDEFICDYLFPDTTFLTELRADIDSISAFLKE RCFQGAAHPVRVSRVVMGGSYDEHTALKGKSEAKMVLFFNNLTSFEEQLKRRGEFVEE IQKHLCQLQQEKPFKVKFEVQSSEEPNSRSLSFKLSSPELQQEVEFDVQPAYDVLYEL RNNTYAEPQFYNKVYAQLIHECTTLEKEGDFSICFTDLHQNFMRYRAPKLWNLIRLVK HWYQLCKEKAEEPLPPQYALELLTVYVWEHSNKNQEKVTTAKNFRTFLELVAYYKNLR IYWTWYYDFRHQEVCAYLCRQLKKARPLILDPADPTRNVAGSDLQAWDLLAKEAQ TWMQSSCFRNCDMSFVPTWDLSPERQECAFQ” BASE COUNT 494 a 487 c 487 g 443 t ORIGIN 1 aaacactcct ggcctcagga tggagaatgg tctctgcagc atccaagcca gggagctgga 61 cgagttcata tgtgattacc tctttcctga caccaccttc cttactgagc tcagagcaga 121 catcgactcc ataagtgctt tcctgaagga gagatgcttc caaggtgccg cccatcctgt 181 gagggtctcc agggttgtga tgggcggctc ctatgatgaa cacactgcac tcaagggcaa 241 gtcagaggcc aaaatggtgt tgttctttaa caatctcacc agctttgagg agcagttaaa 301 gcgacgggga gagttcgttg aggaaattca gaaacacctg tgtcagctgc agcaagagaa 361 accatttaaa gtgaagtttg aggtgcagag ctcagaggag cccaactcca ggtctctgag 421 cttcaagctg agctcccccg agctccagca ggaggtggaa tttgatgtgc agccagccta 481 tgatgtccta tatgaactga gaaacaacac gtatgctgaa ccccaattct acaacaaagt 541 ctacgcccaa ctcatccatg agtgcaccac cctggagaag gagggcgatt tctccatctg 601 cttcaccgac ctccatcaga actttatgag gtatcgtgcg cccaagctct ggaacctcat 661 ccgtctggtc aagcactggt atcaactgtg taaggagaaa gctgaggagc cgctgccccc 721 acagtacgcc ctggagctgc tcactgtcta tgtatgggaa cattcgaata aaaatcaaga 781 aaaagtaacc acagccaaga acttccggac cttcttagaa ctggtcgcct attacaagaa 841 tcttcgaatc tactggacat ggtattatga cttccgacat caagaggtct gtgcctacct 901 gtgcagacag ctcaaaaaag ccaggcctct gatcctggat ccagcagacc caacaaggaa 961 cgtggctggt tcagacttac aggcatggga cctgctggca aaggaggctc agacctggat 1021 gcagtcctct tgctttagaa actgtgatat gtcctttgtg cccacctggg atttgtcgcc 1081 agagagacaa gaatgtgcct tccagtgagc agtgcagcgc ttgctctgaa ggctccagag 1141 tcaggggcat accttcctct gctgcaagac cttgacctag agaggacagg atggcactca 1201 aggctccagt gaggggcatc cagcctgtga tcagactcca ggcttctgat ccctgactgc 1261 ccatggatag ccttcctcac aggctgcttc atctgcctta gcttccaaca gtgttctctg 1321 ggagtcagac tgtgatggac agagaagaac gcaagctcga cttccatctg tccacctgtt 1381 gggaggttct gtccaacagt ggctgattgt catcaacaaa ccacagcaag ccatggggga 1441 gggtgcactc tgagagaagg aacctttaag tacacttgtg tgtctgtgtg tttaaggatg 1501 tggtgtgtcc atatgcaact agaaaccttg agcacgtgtt acaagctcca catgggccca 1561 ggtaattgcc agaaaggggt ggacagagaa aaaccaaact gttacacgta ttgatgttgg 1621 gtagcttggg atccttctag atctctgatg caagaaaccc agactagaat ccatggctcc 1681 tgctgtccat tctcctgtga caaaatttta ggccttcccc atcccacaca gaaactgttc 1741 tccaaccaca catgaccctg gagccctggg aatctggcca gcgtgcatcg tggtgcactg 1801 attctgcagc atgcaggctg aggtccacag cagtgtggga aactatgtgc aatttgtgac 1861 cagtgatgac ttgaaagctt agctgtctgt gtgagggtga gatttgaagc a // (SEQ ID 17) LOCUS AF478457  4380 bp mRNA linear PRI 25-JUN-2002 DEFINITION Homo sapiens ATP-dependent RNA helicase mRNA, complete cds. ACCESSION AF478457 /translation = “MAADKGPAAGPRSRAAMAQWRKKKGLRKRRGAASQARGSDSEDG EFEIQAEDDARARKLGPGRPLPTFPTSECTSDVEPDTREMVRAQNKKKKKSGGFQSMG LSYPVFKGIMKKGYKVPTPIQRKTIPVILDGKDVVAMARTGSGKTACFLLPMFERLKT HSAQTGARALILSPTRELALQTLKFTKELGKFTGLKTALILGGDRMEDQFAALHENPD IIIATPGRLVHVAVEMSLKLQSVEYVVFDEADRLFEMGFAEQLQEIIARLPGGHQTVL FSATLPKLLVEFARAGLTEPVLIRLDVDTKLNEQLKTSFFLVREDTKAAVLLHLLHNV VRPQDQTVVFVATKHHAEYLTELLTTQRVSCAHIYSALDPTARKINLAKFTLGKCSTL IVTDLAARGLDIPLLDNVINYSFPAKGKLFLHRVGRVARAGRSGTAYSLVAPDEIPYL LDLHLFLGRSLTLARPLKEPSGVAGVDGMLGRVPQSVVDEEDSGLQSTLEASLELRGL ARVADNAQQQYVRSRPAPSPESIKRAKEMDLVGLGLHPLFSSRFEEEELQRLRLVDSI KNYRSRATIFEINASSRDLCSQVMRAKRQKDRKAIARFQQGQQGRQEQQEGPVGPAPS RPALQEKQPEKEEEEEAGESVEDIFSEVVGRKRQRSGPNRGAKRRREEARQRDQEFYI PYRPKDFDSERGLSISGEGGAFEQQAAGAVLDLMGDEAQNLTRGRQQLKWDRKKKRFV GQSGQEDKKKIKTESGRYISSSYKRDLYQKWKQKQKIDDRDSDEEGASDRRGPERRGG KRDRGQAGASRPHAPGTPAGRVRPELKTKQQILKQRRRAQKLHFLQRGGLKQLSARNR RRVQELQQGAFGRGARSKKGKMRKRM” polyA_signal 4351 . . . 4356 BASE COUNT 935 a 1293 c 1361 g 791 t ORIGIN 1 ccttctgcgt tcccagcgcg cggcccgaat ggcggccgac aagggcccgg cggctggacc 61 tcggtcgcga gctgccatgg cccagtggag gaagaagaaa gggctccgga agcgccgagg 121 cgcggcctcc caggcccgcg gcagcgactc ggaggacggc gagtttgaga tccaggcgga 181 agatgacgcc cgggcccgga agctgggacc tggaagaccc ctgcccacct tccccacctc 241 ggaatgcacc tcggatgtgg agccggacac ccgggagatg gtgcgtgccc agaacaagaa 301 gaagaagaag tctggaggct tccagtccat gggcctgagc tacccggtgt tcaaaggcat 361 catgaagaag gggtacaagg tgccaacacc catccagagg aagaccatcc cggtgatctt 421 ggatggcaag gacgtggtgg ccatggcccg gacgggcagt ggcaagacag cctgcttcct 481 cctcccaatg ttcgagcggc tcaagaccca cagtgcccag accggggccc gcgccctcat 541 cctctcgccg acccgagagc tggccctgca gaccctgaag ttcactaagg agctaggcaa 601 gttcactggc ctcaagactg ccctgatcct gggtggagac aggatggaag accagtttgc 661 agccctgcac gaaaatcccg acataattat tgccacgccc ggacggttgg tgcatgtggc 721 tgtggaaatg agcctgaagc tgcagagtgt ggaatacgtg gtgttcgatg aagctgaccg 781 gctttttgaa atgggtttcg cagagcagct gcaggagatc atcgcccgcc tccccggggg 841 ccaccagacg gtgctgttct ccgccacgct gcccaaactg ctggtggaat ttgcccgggc 901 tggcctcacg gagcccgtgc tcatccggct tgacgtggat accaagctca acgagcagct 961 gaagacctcc ttcttcctcg tgcgggagga caccaaggct gccgtgctgc tccacctgct 1021 gcacaacgtg gtgcggcccc aggaccagac cgtggtgttt gtggccacga agcaccacgc 1081 cgagtacctc actgagctgc tgacgaccca gcgggtgagc tgcgcccaca tctacagtgc 1141 cctagacccg acagcccgca agatcaatct cgccaaattc acgcttggca agtgctccac 1201 tctcattgtg actgacctgg ccgcccgagg cctggacatc ccgctgctgg acaatgtcat 1261 caactacagc ttccccgcca agggcaaact cttcctgcac cgcgtgggcc gtgtggctcg 1321 ggctggccga agtggcacag cctactcctt ggtggcccct gatgaaatcc cctacctgct 1381 ggatctgcac ctgttcctgg gccgctccct caccctcgcc cgacccctca aggagccctc 1441 aggtgtggcc ggtgtggatg gcatgctggg tcgggtgcca cagagtgtgg tggacgagga 1501 ggacagtggt ctgcagagca ccctggaggc atcgctggag ctacggggcc tggcccgcgt 1561 tgctgataac gcccagcagc agtatgtgcg ctcacgcccg gcgccctcgc ctgagtccat 1621 caagagggcc aaggagatgg accttgtggg gctgggcctg caccccctct tcagctcgcg 1681 ttttgaggag gaggagctgc agcggctgag gctggtggac agcataaaga actaccgctc 1741 ccgggcgact atctttgaga tcaacgcctc cagccgagac ctgtgcagcc aggtgatgcg 1801 cgccaagcgg cagaaggacc gcaaggccat cgcccgcttc cagcagggac agcaggggcg 1861 gcaggagcag caggagggcc cagtgggccc agccccgagc cgcccagcac tgcaggagaa 1921 gcagcctgag aaggaggagg aggaggaggc gggagagagt gtggaggaca ttttctcaga 1981 ggtcgtgggc cggaagcggc agcggtcagg acccaacagg ggagccaaga ggcggaggga 2041 ggaggcccgg cagcgggacc aggaattcta catcccctac cggcccaagg actttgacag 2101 cgagcggggc ctgagcatca gcggggaagg gggagccttt gagcagcagg cagctggcgc 2161 tgtcctggac ttgatggggg atgaagccca gaacctgacg aggggccggc agcagctcaa 2221 gtgggaccgt aagaagaagc ggtttgtggg acagtcagga caggaagaca agaagaagat 2281 taagacagag agcggccgct acatcagcag ctcctacaag cgagacctgt atcagaagtg 2341 gaaacagaaa cagaaaattg atgatcgtga ctcggacgaa gaaggggcat ctgaccggcg 2401 aggcccagag cgaagaggtg ggaagcgaga ccgtggccaa gcaggtgcat cccggcccca 2461 cgccccaggc acccctgcag gccgagtccg cccggaactc aagaccaagc agcagatcct 2521 gaagcagcgg cgccgggccc agaagctgca cttcctgcag cgtggtggcc tcaagcagct 2581 ctctgcccgc aaccgccgcc gcgtccagga gctgcagcag ggcgccttcg gccggggtgc 2641 ccgctccaag aagggcaaga tgcggaagag gatgtgagga ccaggaccca gccccgtggc 2701 tccttgattg gccttagggt gggcatcagc agacgttccc gtgcaccact gtgtgcctgg 2761 ccctgtgctg ggcactgggg gcactccctg caggagccat catctgtgaa aaggagcact 2821 gtatggccac agaagggcag cagctgcgtc agcctaagac agagacattt gaacagggcc 2881 ttgaagggtg tgcaggagtt cgccagcaaa gccaggcagg ccaagacttg agttggcaac 2941 tcagctgctg ctgcttccat gtgttctggg ttcagaggtc atggctgcac cggtcagagc 3001 cctgagtgcc tcagggtttg gcaatggaat ttttaatgta ataaatcttt attgagcact 3061 gctggtggcc aggagtgcgg tctacttggg gaactggaat ggagagaccc aggtactaaa 3121 atcccagcta acgtggcaga ggagttgcgg gtctcctgag ggtgagttct gctgccttgt 3181 ccatttagcg atgaggaaag tgaagctcag agcacaaacc aggtgccaga ggcgggagtt 3241 ggtccccctt cctcccactg gacatggttg cagctgggag tgggctgggg gaggggaaca 3301 ggatgcccag cccagggggc aaggacacag ctgctcccct ctggctatga agaggttaac 3361 gcggcccctc cacacctgga ggtcagaacc tggcctgtcc tctgtcttct tgccacccac 3421 cccctgtttg aggttctgag aaggtcaagg gcagccccag cagctggatt ctcaggctgg 3481 gcccctcacc tggcagagtc catagtggag ggggccttgg tgatctctca tctagcatgg 3541 accctgttct gagacctgac aaagagtttt ttttcatgcc ccaaccaccc tggcagggag 3601 ggcctggtct gatctcattt tagaggcagt tgccccacac atagcccctt gaccttccca 3661 tcacctcctc atcagggcct gcatttatgg agtgcttgct atgtgcccct catggcaggc 3721 ccacagcact ctgaacaggc acagccctcc catcttccca atgaggaaac ggattcagga 3781 agagccactc agtccacacc ccattggaaa tgtgggccct cctatctcag ggtctctcag 3841 gggttccctc tcccgctgct cacctgtgtc agggctagga ggcaggggct gcaggctcag 3901 cctgacccag gccggccagc atggcagaga ggtcctgcat gaacagcttc acctgggggg 3961 gcccagcacg aagtcacatc ccagccccag agtcactgtc cagcccccac ccctcaacac 4021 gcgggggagg ccgaaaggta gggcggggac tggagatccc ctcattaaaa gaacagtgat 4081 gatggtggtt cccagaggtg gtgactgaga tcctaaaccg ttctgggttt tgaaagcctc 4141 aggccaacct tcccaactgc tgcgtgagca gacaccttca cagcttcctc gctgctgtca 4201 cctgcactat ccaattagta ttttcattta catcaatcag ctttattttc ttgtaactgg 4261 atcagtcata ttcattggtt tgtgacctac tcttatctcc gtgggtggct ctccttttgt 4321 tttaattaac ttctttatga atatgaactt aataaatacc atggatccat tgtaaaaact // (SEQ ID 18) LOCUS AF480417  1993 bp mRNA linear ROD 26-JUN-2002 DEFINITION Mus musculus 2′-5′olygoadenylate synthetase 1G (Oas1g) mRNA, complete cds. ACCESSION AF480417 /translation = “MEHGLRSIPAWTLDKFIEDYLLPDTTFGADVKSAVNVVCDFLKE RCFQGAAHPVRVSKVVKGGSSGKGTTLKGRSDADLVVFLNNLTSFEDQLNRRGEFIKE IKKQLYEVQHERRFRVKFEVQSSWWPNARSLSFKLSAPHLHQEVEFDVLPAFDVLGHG SINKKPNPLIYTILIWECTSLGKDGEFSTCFTELQRNFLKQRPTKLKSLIRLVKHWYQ LCKEKLGKPLPPQYALELLTVYAWEQGNGCNEFNTAQGFRTVLELVINYQHLRIYWTK YYDFQHKEVSKYLHRQLRKARPVILDPADPTGNVAGGNPEGWRRLAEEADVWLWYPCF MKNDGSRVSSWDVPTVVPVPFEQVEENWTCILL” BASE COUNT 493 a 495 c 537 g 468 t ORIGIN 1 gccaggctgg gagacccagg aagctccaga cttagcatgg agcacggact caggagcatc 61 ccagcctgga cgctggacaa gttcatagag gattacctcc ttcccgacac cacctttggt 121 gctgatgtca aatcagccgt caatgtcgtg tgtgatttcc tgaaggagag atgcttccaa 181 ggtgctgccc acccagtgag ggtctccaag gtggtgaagg gtggctcctc aggcaaaggc 241 accacactca agggcaggtc agacgctgac ctggtggtgt tccttaacaa tctcaccagc 301 tttgaggatc agttaaaccg acggggagag ttcatcaagg aaattaagaa acagctgtac 361 gaggttcagc atgagagacg ttttagagtc aagtttgagg tccagagttc atggtggccc 421 aacgcccggt ctctgagctt caagctgagc gccccccatc tgcatcagga ggtggagttt 481 gatgtgcttc cagcctttga tgtcctgggt catggtagta tcaataagaa gcctaatccc 541 ttaatctaca ccatcctcat ctgggaatgt acctccctgg ggaaggatgg cgagttctct 601 acctgcttca cggagctcca gcggaacttc ctgaagcagc gcccaaccaa gctgaagagt 661 ctcatccgcc tggtcaaaca ctggtaccaa ctgtgtaagg agaagctggg gaagccactg 721 cccccacagt atgccctgga gctactcact gtctatgcct gggaacaggg gaatggatgt 781 aatgagttca acacagccca gggcttccgg accgtcttgg aactggtcat caattatcag 841 catcttcgaa tctactggac aaagtattat gactttcaac acaaggaggt ctccaaatac 901 ctgcacagac agctcagaaa agccaggcct gtgatcctgg acccagctga cccgacaggg 961 aatgtggctg gtgggaaccc agagggctgg aggcggttgg ctgaagaggc tgatgtgtgg 1021 ctgtggtacc catgttttat gaaaaatgat ggttcccgag tgagctcctg ggatgtgccg 1081 acggtggttc ctgtaccttt tgagcaggtg gaggagaact ggacatgtat cctgctgtga 1141 gcacagcagc acctgcccag gagactgctg gtcaggggca tttgctgctc tgctgcaggc 1201 ccatgaccca gtgagggagg gccccacctg gcatcagact ccgtgcttct gatgcctgcc 1261 agccatgttt gactcctgtc caatcacagc cagccttcct caacagattc agaaggagag 1321 gaaagaacac acgcttggtg tccatctgtc cacctgttgg aaggttctgt ctgacaaagt 1381 ctgatcaaca ataaaccaca gcaggtgccg tcatggtgtg tgaactctga ggagtgggcc 1441 atacaagaac agtgcaggtg tgtgagcgtg tgtgtgccca tgcacatgcg tgtgtgtctt 1501 cacggttcaa ctagatgcat ttagtgagca cttactacat atgctacatg attcagatgt 1561 tcagcagtgg ttagagcaaa gcctaactgc taggcttttt gatgcaagtt ggattgggat 1621 ccttccaggt ctcttcttac acatacacac aagagaggaa cccttggttt cttctgccca 1681 tgaccccaag acaagattct agccctgccc tatctgacac agaaacagtt ccctggccac 1741 acatggacat ggaacactga gactgtggcc tgtgctctca gggtgccctt gagtggctac 1801 aacatgcagg ctgggggccc ataggtatga tgaaaataaa aggtacctgg aatttttgac 1861 acatgtaact ttgaaacagg gtcattggta gcaacgatca gctttatcac atttagttaa 1921 atcacaatga ttgtggtttc ctttctgaga catgaatttg atgtgacaca cgctgtcgtg 1981 gaactcacag gaa // (SEQ ID 19) LOCUS AF481733  1476 bp mRNA linear ROD 25-JUN-2002 DEFINITION Mus musculus 2′-5′olygoadenylate synthetase 1F (Oas1f) mRNA, complete cds. ACCESSION AF481733 translation = “MVKDLSSTPACELDKFIRDHLLPDSSFHAEARADVDFIGAFLKE RCFQGATHPVRVSRVVMGGSYDEHTALKSKSEAKMVVFLNNLTSFEEQLKRRGEFIEE IRKHLCQLQDEKPFKVKFEVQSSEEPNSRSLSFKLSSPELQQEVEFDVQPAYDVLYEL RNNKYAELYLYNKIYAQLIHECTTLKKEGEFSICFTDLHQSFLEDRAPKLKNLIRLVK HWYQLCKEKLGKPLPPQYALELLTVYAWESGSRDCEFNTAQGFRTVLELVTKYKWLRI YWTVYYDFRKTKVSEYLHKMLQKVRPVILDPADPTRNVAGTNLLGWGLLAKEAAIWLQ SSCFRNCDTCLVGPWGVPVKVEIPQDCVLL” polyA_signal 1459 . . . 1464 /gene = “Oas1f” BASE COUNT 378 a 391 c 385 g 322 t ORIGIN 1 tcagcaaaca cttcctggcc ataaaatggt gaaggatctt agcagcaccc cagcctgtga 61 gctggacaag ttcatacgtg atcatctcct tcccgattcc agcttccatg ctgaggccag 121 agcagacgtg gacttcatag gtgctttcct gaaggagaga tgcttccaag gtgccaccca 181 ccctgtgagg gtctccaggg ttgtgatggg cggctcctac gacgaacaca ctgcactcaa 241 gagcaagtca gaggctaaaa tggtggtgtt ccttaacaat ctcaccagct tcgaggagca 301 gttaaagcga cggggagagt tcattgagga aattcggaaa cacctgtgtc agctgcagga 361 tgagaaacca tttaaagtga agtttgaggt gcagagctca gaggagccca actccaggtc 421 tctgagcttc aagctgagct cccctgagct ccagcaggag gtggaatttg atgtgcagcc 481 agcctatgat gtcctgtatg aactgagaaa caacaagtat gctgaactct acttgtacaa 541 caaaatctac gcccaactca tccatgagtg caccacacta aagaaggagg gcgagttctc 601 catctgcttc accgacctcc atcagagctt cctggaggat cgtgcaccca agctgaagaa 661 cctcatccgt ttggtcaagc actggtatca actgtgtaag gagaagctgg ggaagccgct 721 gcccccacag tatgccctgg agctgctcac agtgtacgcc tgggaaagtg ggagtagaga 781 ctgcgaattc aacacagccc agggcttccg aactgtcttg gaactggtca ccaagtacaa 841 gtggcttcga atctactgga cagtgtatta tgactttaga aagacgaagg tctctgaata 901 cctgcacaaa atgctccaaa aagtcaggcc tgtgatcctg gaccctgctg acccaacaag 961 gaacgtggct ggtaccaacc tactaggctg ggggctgttg gcaaaagaag ctgccatctg 1021 gctgcagtcc tcctgcttta ggaactgtga tacgtgcctc gtgggcccct ggggtgtgcc 1081 ggtgaaggtc gagattccac aggactgtgt ccttctatga gcaccaaagc acctgccagg 1141 atgctcaaga gtcagggata tgagatcctt gctctgctgc aggcccttga accagagaag 1201 ggggaaagct gctcacggcc ccaatcaggg agggtccaac ctgtgatcag actccaggct 1261 tctgacccct gccttctcac ccctgcatcc ggtcctatca cagatagect tcttcgaagc 1321 ctgctttatc tgccttatcc accaacagtg tcctccggga gatgagagat tcagaattca 1381 gaaggggagg caggaactca agcttgactt ccacctgtcc acctgttggg aggttctgtc 1441 caatgtctga tgcacaataa taaatcacag agagcc // (SEQ ID 20) LOCUS AF481734  13943 bp DNA linear ROD 25-JUN-2002 DEFINITION Mus musculus 2′-5′olygoadenylate synthetase 1b (Flv) gene, Flv-C3H.PRI-Flvr allele, complete cds. ACCESSION AF481734 translation = “MEQDLRSIPASKLDKFIENHLPDTSFCADLREVIDALCALLKDR SFRGPVRRMRASKGVKGKGTTLKGRSDADLVVFLNNLTSFEDQLNQQGVLIKEIKKQL CEVQHERRCGVKFEVHSLRSPNSRALSFKLSAPDLLKEVKFDVLPAYDLLDHLNILKK PNQQFYANLISGRTPPGKEGKLSICFMGLRKYFLNCRPTKLKRLIRLVTHWYQLCKEK LGDPLPPQYALELLTVYAWEYGSRVTKFNTAQGFRTVLELVTKYKQLRIYWTVYYDFR HQEVSEYLHQQLKKDRPVILDPADPTRNIAGLNPKDWRRLAGEAATWLQYPCFKYRDG SPVCSWEVPTEVGVPMKYLFCRIFWLLFWSLFHFIFGKTSSG” polyA_signal 12974 . . . 12979 /gene = “Flv” polyA_site 12996 /gene = “Flv” BASE COUNT 3434 a 3551 c 3318 g 3640 t ORIGIN 1 catccttttt ttttttttcc attcatttct tcatctgttt tagggttttt tccccctcac 61 actctggagt gaatccagct gtagtgtagc ccaggatgga ccagcctcca ctatccatcc 121 tcctgcatca gcctctgcct gctgaactgc tagggccacc cacaatgctg tttttcttcc 181 ctgttttcct gcatgtgaag ggctaatgac ctagaagccc caggcagtct gagtgactcc 241 ctgcaggagg agatatggtg ctgatgtcag tgtgcagtga ggatcaggga ggccaacggg 301 gtaagcaccc caccaaaatc caccagcttg gggaagcagg actaggtctg cagaccccca 361 aaggtcccat ttccacccta atcccctgga gctccctgtg cccggtgagc agtctccact 421 agcaatggct tccttcctgg agatgcataa aggccaatcc tgctcttgca gaaggccaga 481 ctctttattt cctcatcgaa gtacatcctg gttaatgctc gggtgtgcac atgtgagtat 541 acacttgttt gtgtatttgt gtgcatatgt gcacaggcaa gctcaggagt gtatttagtg 601 tgtgcatgcc ctgtgcgtgt gcatgtgaat gtgtgtgtgt gtgtgtgtgt gtgtgtgttt 661 gggacctgcc atgtcagttc tcagaattgg aactggaagc acagcccgag ctcttaaact 721 ctgagccctc tctctgccct ctaaacaaga gatgagaaga tggaggcagg ggttggaggg 781 catcaaactg ttttgatgag gccttgggta tgtcacccaa aggtgatttt caaccttgcc 841 agggccctga aagacagctc attttaatag tcactgctga cctgtactgt ccccagcttg 901 gtggtacggc ctgtacttca cccttgggga tgcccagacc ccaccctcac ccagaccccc 961 tgcaccacag gggaaaatgt agggtgtgag taggagaggg ggcttctggg aagtctgagc 1021 tttctgttag aattgtctgt aatcctagac ctgcaagtcc agaggtaaag gaaaaacaaa 1081 acctggggag gtgctgttct taaaaagaaa aaaaaaaaaa aaaagcagtt ccgcctaaaa 1141 cgtttgcagg agatggaagc cgagctcagg agccaccagc caccttctgt ggtttcctga 1201 ttccgtttcc cttcttctac gtgcacagat tgttcctaaa acgtaccgtg taacagcctt 1261 ttttccagaa gaaatcccga gaaagccagg tcagtttcct tacacattct tccctgggcc 1321 ggatcttaag aaagctcagg cttggatggg gaggtacctg ttcagaagcc ctaacgccat 1381 tggctgctcg ggcctggatg atttgcatat ccgcgccctt cccgggaaat ggaaactgaa 1441 agtcccattt ctgcttcagc gagcctagga gacacaggac ctgctggctg cagaggtatt 1501 agctggacct aggatggagc aggatctgag gagcatcccg gcctcgaagc ttgataagtt 1561 catagagaac catctcccgg acaccagctt ctgtgctgac ctcagagaag tcatagatgc 1621 cctgtgtgct ctcctgaagg acagatcctt ccggggcccc gtccgccgaa tgagggcctc 1681 taaaggggtc aaggtgagcc ttcctcagcc tgagctggcc gagatgaggt gggacaggac 1741 tttcagaagc caggctgcaa ccctgatccc tcctcttaat tctgatcaca gctggcgatg 1801 ggttcttccc cccaagtccc acatctgtat tggagaagga gcctcagcta cagtttatgt 1861 tccccactcc caggccatgt ccatttcaga gtcggggaaa ctgaggccca gaatggcaaa 1921 gcagttttct ggaaagtgga ggggcaggtg gtggggcagt ggtaatacaa cctttgcact 1981 gctgtgtgac ttatggtaac ttaactacct tctccatgtc cagtgttcca cgccccagga 2041 atgataaggt cacatagact aagtcaaatg tgacacggag gacagaccag gactcgcctg 2101 ctatgtgact ggattgatgg accctctctg gactcggttc ccgggctgtc tgtcaaatca 2161 catttcatga cactggtact taactctcag actctgtgaa gggtgcagaa atgaagttgt 2221 tttcttgttt tcagttgact gtatttctac atttttagtt gtgagtgggg ctctgtatgt 2281 gttagtgcag gtttggtcag aattgaaaag ggggtgtcag atcccttaga gctgcagtta 2341 cataggtggc tctgagctgg cctgcttggg tgctgggaac taaactgagg tcatcagcag 2401 gaacagcagg cagttttagc tactgaccca cctctccatc cggagatgtg acaatttgta 2461 atgccctctc tcaacagtag ctgatgctta tgtgtgttag tgatgattct aagcatttta 2521 tttagggagg ctttgttcag catgaattct tctttttatg atatttgttt tacagacttg 2581 gatcaccttt attgtttttt tcagtttctc tatgatgtta tatgttattc tatatcacac 2641 aaggccatct tctctttaat gatgtcactt gcgcatattt cctcccagct aacaatgcca 2701 accatgggac tatggctaca ttctcatata tctgtattaa tttagtcata gtctccttcc 2761 aatctctact atcctttacc tcccaccaga ccctccccag agattcactc tctgatggta 2821 tgtcacatgt gtgcagctaa tgtgggcact gcatgagtgc tactgtaccc ttcccaaact 2881 cttctgtgct tgtttcattt agacctctcc cccactccca tacacagccc ccccccacac 2941 acacacacac ttgaacacac agagactcca cagatgaaca tggatatttt ccttcacggt 3001 gtggtttatc ttctgtatca agaggagatc cagcaccctc tattttccta catagattct 3061 gatgtcactc ttcagggctg actaatattc tcctgcacat ctagcagctt gctccatcca 3121 tccaaccatc catccatcca tccatccatc tatcaccttg gtgatggact ccagttcagc 3181 atctggacct cccagcatgg ctctccctgt cctttgtcat tctctttctt gtctttcagg 3241 gcaaaggcac cacactcaag ggcaggtcag acgctgacct ggtggtgttc cttaacaatc 3301 tcaccagctt tgaggatcag ttaaaccaac agggagtgtt gattaaggaa attaagaaac 3361 agctgtgcga ggttcagcat gagagacgtt gtggagtgaa gtttgaggtc cacagtttaa 3421 ggagtcccaa ctcccgggct ctgagcttca agctgagcgc ccccgacctg ctgaaggagg 3481 tgaagtttga tgtgctgcca gcctatgatt tactgggtaa ggcagcctgc cagagagcct 3541 cagctcaccc ttctgcatgc cttcatcctc ccttctagtt ccacctctgt gtgtgtgcac 3601 atgtgtgttg cgtaggtgtt ctcttgtgtg tgggtgtgat ccggaaccat ggctaactca 3661 tctcaagagt catccatctt ttttgagacc ttgtctctcc ctggttcaga attcacactt 3721 gagcctgact ggctgggaag agccccaggg accctcagag tctccccctt ctcagttctg 3781 agattacaat cctacaccac caacactggc tttttctctg agttctggga ttccgacggg 3841 ggtcctcatg cttgcgagcc aagcacgtta cagactgagc tatctcccca gcccacacct 3901 tccatccctg aactgaaaac cattatcatt tgagaaattc aactaaagag aatgtctctt 3961 taaagctgcg ctggggagga gggattttgg aaatttggta gcggggagac agaatccatc 4021 ccacagggac attgagcagc ctgctggctc acttagggga gggagtcaca ctagatgctc 4081 cctcagcata ccagtcctac tcacggctag ctgtgggttt tgtcttctta aacatgagac 4141 agtgtagact tcactgaaaa taacaaactc gcgaattttc tccctcagag ctgttcagag 4201 acctggggtg tctgcaggag agtttgcaca ggacgcagat ctcatcggag ctctggcccc 4261 tcagtaaaac tgcagatgca gacacccaac tcacacatgc acacacattt tataacatta 4321 cacattaaaa gatcttatct tttgacaaaa atctcaatta ttcaatttta ccaatgaaga 4381 cttgcaaagc cagatactgt ggtaaaatcc tgctagctca gggaggcaga gaaagcacct 4441 agctgacctt cctcctgagc cagaatgttc cagaatgcat ccccttctca tgctatctca 4501 taacctcttt caaatggaat gtccctcccc tctacttcct gtgggtctct ctatccctcc 4561 ttctgactcc ctcttactct ctgtggttcc ttcttagtaa tcccatgttc gcttctggtc 4621 agctggttgc ttgctctgcc tcttgatcta tgattggctt tatttaatcc tgtttacaat 4681 attcaagcag aaagctcctg gattaagggt gtgtgctaag gctgagccac cacacctaaa 4741 accagttttt tccaataaac aactcaatct cagggttcac agtgtgatca aatatcctgc 4801 aacaatcttt taccaggcct gatacagcat gcgtcgccaa aattacagat tgtccaactc 4861 aggaaacact cctgagagca cagtgggatc ttgggggagc ttagagaata cttgaggctt 4921 tacatttggg ggaagcacag caccccctgt tggccactgt gtgaacttct gctgttaact 4981 tagtgacaag gccactagcc cttggcttag gagagccgtg gaaacagtcc agagtctcag 5041 gcagcaggga ctgagagggc cagcctggga gtaggaccag ggcagcctgc tgtgggaagc 5101 tgcaagaggc ttagaacctt gttcagtgga gggggatcag agtgggtgac cagaaatgat 5161 ctgtgacagc aggtcccaca gaagcctgtc tgggtcatgg atttcctcag cctcagcagc 5221 tttccagtgg tgaggggctc taccacagaa ggactgcctg tgggcaacag ccaaagagag 5281 gatcatagcc acagccctat agaagatgac ataaagcaat gagccctatt gtaactagac 5341 cctgacacta atctagacta gcccataacc tccatggtca ctgagtgaca ggcttgtcga 5401 agctccatcc gtgagtgact ttgccctgtg tcagcatcac agtctgatgg tgtggtctgc 5461 tgcatggcac acatgtgcac acacctaagg cacagcctgc ctagactact caaatgtgca 5521 cacacaccta tacacacatc tattccatag tctgctgctc ttctactcta taagtgcaca 5581 ggacacacac acacaaacac acacacaccc taacactgcc atatcttgtt ccatctggac 5641 aaacaaaacc acatgatatt aacttatcac tacaagaaat cacccaccga aaacacacag 5701 tggctgggga gacagctcag tggataaggg cgattgctgc tcaagcatga gtacctgagt 5761 tcaaatcccc aatatccacc taaacttagg aagtgccaca cattgacctg gatacctggt 5821 cactatgggg gcaaaagaca ggagattctg taagacctgc aggattccag ccaagctcca 5881 catttacaga cagactctga cgcaaagaaa catactgaca aactataaag aagagacacc 5941 ttaggtcctc tcctgtctct gaacatatca ggaacactcg ccatgcatac acaatataga 6001 gcagagactc tgtcagtgtg agacgtgata tgtgaatgca gccgactgct ccacagtgaa 6061 ctttgacaca tacatgagtg cacaactttg acaagaacta tgcagaagat actggaacca 6121 gacgtggttg gccattatct gatgatcacg tgtgtgtgac cacagtgtgc tggttcctcc 6181 cacctctgtc tccaggcctg caagaaagac cctcactaga gcaaactggg agcagggact 6241 ttgtagtgca cagcatgtgt gcagtcctaa ggagtggtgg ggcagatggg tatatgcgga 6301 gcgatgcctg ctggggaaaa acgctgcctg ttcgctgaac cccataggct gtgattctgg 6361 acctggggag actgaggaac ctcagagagg ggctgagctg ttccactgaa tgaaatcttg 6421 tttacagatc atcttaacat cctcaagaag cctaaccaac aattctacgc caatctcatc 6481 agtgggcgta ccccgccggg gaaggagggc aagttatcga tctgctttat ggggcttcgg 6541 aagtacttcc tgaactgtcg cccaaccaag ctgaagcgcc tcatccgcct ggtcacgcac 6601 tggtaccaac tggtaaggca ttggcctggt cactgtgcgc ttcatctgta cagagtgtag 6661 acagggggca gagaaaatgt gtactctagt tcggcgtcta ttgaggtaat aactctatca 6721 catgaccaaa acgctcctgg gaaggaaggg tattcttatg tttacacatc taaggcacac 6781 tccatcattg agggaagtca gaggaataac tgaagcagag gccatggagg aattctgctc 6841 accgtttgct gtccatgacg cactcagcgg ccatttctac acagcccaag gccacattcc 6901 attcatggct ccaaccacag tggtctggtc ccacccacat caatcagtga ttagtaacat 6961 gcccataaac tacccaagcc agtcagatgg atctgcattt tactgagcaa gatggactcc 7021 taccagagga ggctagctgg tgtttagtgg acaaaaagta agcagcacaa ttgacccctt 7081 ttcaacatgg cacacaaaca aaccacagtt gaaccataac ctttcccttc ttgcttgtcc 7141 ctaagatctc atgtcgctat cacaccatag aacacaactt aggtttaaag tccccaaatt 7201 aaaaatcaaa cctaaagaaa ctcccaacac ataaaaagac tagtctctca atgctggcct 7261 catataaaat taaaacacaa gttaaatact ttcttactgc aagagggaag aaccaagtca 7321 ctgtcacaat ctaattaaaa cacaaccaaa attcaacaga acaaaaggct cagtatctga 7381 tatctgggac tcatagttct ctgagctttt tgggctctgc catccacagc acacacagca 7441 ggtctcaggc tcaggccagc tttgttctca cagtgctctg ttcctgacag tcatctcctg 7501 ctcagggcaa ggccagtatc ttggggtttc cactgccatt gaggctgcac tttcactaat 7561 ggcttctcct ggcctctcgc agtgccaggc ctcagctgct ctccaaggcc ccttcagtcc 7621 agcagttctc atgggacttg aaatctggga gacatctctg cagttccagg tgtgattgac 7681 acttggagat gcagacttgg gacccctgga ctacagctga tagagtccat ggtctgccaa 7741 agaatgatgt cctgcactca aattgtatgc aaaagcaaag agcgttttta ttctgtggag 7801 tccagcatgc tgggatctat cattaaccaa gatggagatg cccagatgag atcacaggct 7861 caatttaaag cacattagtg gaattccatg gaagagtagg tgaccttttt cttgattggt 7921 tggctctatt ctagggacat tcctgaatca ttactggggg gctagaaact gtcacttggg 7981 gaagcctgga aactgttgct gactctgttc tttccctagg ccaggtggca gggaagcttc 8041 tgatggctgg gcagtttctg attggatgct ctaggcctgg ggtttttcca ataaatgact 8101 tgcctggact tgtacagttc tgagaaacac aaattcaggc ctagtctcct gatatgccag 8161 tttgaagccc attatggaat caccctggct cagtccactt acacctactc ttgctgacta 8221 tgaagaaact ctttccaaaa gatttgcacc ccccccccca cacacaccca tggtgcaggt 8281 ttcttcttta tcagagcaga ttttcagccc caactgatga gaaattactg actcttaatg 8341 taaacacagc acacaaacag cccagatggg tttttgcttt tctctgaaac ttcactccag 8401 cctctgtcac ctacctgcct ctcagcactc ctgtcttcca agttcccaca aacagcctgg 8461 taggctctca gctctcaaca gctctcccac ccaaagttcc ataatccttt ctcaatcctc 8521 ccaaggagca acatggcagg tcagtcacag cagcgcccct cctccctagg accagtttct 8581 gtcctagttt gctctgactg ctgtggtaaa gatgctgcaa agtaaattga ggtggaaatg 8641 gattgtctgg ctcacgttcc tgcatcacac tccatcactg agggaagcag aggcaggaac 8701 tgaagctgag gccatggagg aactctgcta gctgccggag acccttgggc gatcagtctg 8761 atttttacaa acaactcagg aacacctgcc cagggcaggc aatgcccaca atgggcgggg 8821 cccttctaca ctgatcaagg aaatgcccca caggcttgac tccaggccag gctgatggag 8881 gcattttctc agttgtgggt ccatcttctc cagatgattc tgtgtcactt tggcaaaaag 8941 aatcaaaatt agcaaaagca gtgagaaaaa caatgtaaaa aaaaaaaaaa agtgggtgga 9001 ggggaatcag aggggagggg atgagagaga agcaggggtg agtggagatg gggggagatg 9061 atgctgtagg aggggcaagg agtggggtgg gggatctgag aggagggagg attttccttg 9121 cctgttctag gtgatttctt ctagtccact ttccaatccg ctaactctct cttcagctgt 9181 gtctgattca ctgttccatg gcttctgctt catttgtctt tggatttttc tcccattgtt 9241 ggcaaatcct tcatgtcact tttcatactt tgattttcct gtcttgtcaa gctatgtttt 9301 taaatgtgtg atttcttatt atatcctgag tgtttttatg tgtatgtgtt tatacctatt 9361 cttggaaaca cacgtgtatg tgtaggcatg tgtgtccatt aggatttgag ggcagagtgt 9421 gagagcaggt tctgagtcac gccccacctt gtgtaatcag tcagggtttc acacgtgaca 9481 ctccgtgtgc tagattagca gttctggaca gtcatacagc ccgggggagc cccatcttta 9541 tccccttgaa cagggatgag gagtcagctt cctcaagagc ctgacaacac atagatgctg 9601 gggatctgac ctccagttct catccctgca tggggaggga ggcgctttac ctctgagccc 9661 tttatctccc tggccccttc ccagttactt cagagaccac aagcgaactt ctacagtgag 9721 tactccttat gtcctgcccc accctcactc ctagctgtca ctcatggtgt cctgattcct 9781 cctgggcctg ttagttacgt gctcagtctg tggagcacac agtgtccatc tcaaccgctc 9841 agctcttggc tatagcacaa gaaggcatag actgaattca agtgactggg tgtgacagtg 9901 tgacaataac cctgtcatga catcatcagg tggcagctga attgagcctg tgagaagcag 9961 ccccacacac aaccaccagg aaccccgttt tttttctcat tgcctttctc ttctcagtgt 10021 aaggagaagc tgggggaccc gctgccccca cagtatgccc tggagctgct cacagtctat 10081 gcctgggagt atgggagtcg agtaactaaa ttcaacacag cccagggctt ccgaaccgtc 10141 ttggaactgg tcaccaagta caaacagctt cgaatctact ggacagtgta ttatgacttt 10201 cgacatcaag aggtctctga atacctgcac caacagctca aaaaagacag gtagtctgtc 10261 cccacatgcc tgtgatcccc gtggagtgtc aggctgcact tgtgtttaaa gggggaggtg 10321 ggagctctgt gtctatgcag catcccctgt actgagcact gtcctgctgt cacctgattg 10381 acatgaggtc ctacagccct gggaggcagg ggtgggctct cctgtctgca gatgaggaga 10441 ccaaggctct gacattgtcc caacccaatc agcaaaggaa aggggggggg gacatggagt 10501 ggggactgag attttccaac agtgacagca tcataaaggc tgtgaggcac caaagacctg 10561 aggtggacaa attacctgta aataatacag tgctatgtca ccctagggag tgacatgtct 10621 tcattctgtg ttgtgttcag tttccacacc ctattctttg agcctggctg gtccaacact 10681 cttcatgtca cagatcagag accctgaggg atctgtccca ggacacacag ctactaaatc 10741 atgcccaagg atccctccag gcttctatat gctgtggggc agggacaaaa aaaaaatctt 10801 tgaaaaggag ctctctgctg ggctcctccc ccacccctgt gcagtggttc ctgggtcagt 10861 tgacagcagc tcgtttccct ctcttcatgt tgctctgcag gcctgtgatc ttggaccccg 10921 ctgacccaac aaggaacata gctggtttga acccaaagga ctggcggcgt ctagcaggag 10981 aggctgccac ctggctgcaa tacccatgct ttaagtacag ggacggttcc ccagtgtgct 11041 cctgggaggt gccggtgaga acgtgtcacc atcatcttca ttccacaccc cccccccttc 11101 tcttcatcta cctggagaat cttcccacac agatgtggtc tccgcactcc tgtggaggcc 11161 attggctctc cttattccac agccatctta gcgctattca cagatttcat ggactcacag 11221 gatggctcag tgggtaaagg tgcttgctgc caacacagat gacctgggtt tcatcccagg 11281 atctcctatg gtagaaggag agaatcaaat ccccaaagtt atcctctgac cttcatctct 11341 gctgttacac acagggacat gagtgtgtgc atacacacac atacacatac acacacacat 11401 gtcactacac ccacccaccc acctatccac aggttgcccc caaccaccac cacatagaca 11461 gacacacaca aaaatacaca aacacagagg ttgcccacac ccattcacac aaagacacac 11521 acacagacac acacacacag acacacctac acacacacac accatcatca tcatcatcat 11581 catcatcatc cacaaataga taacacacat acatagactt ggagacctga agccactggc 11641 tcggggacac tcagatagag tgaagaacgg ctgggacccc gtggactctg aagcccctgt 11701 caggtccatg aagcagcctg tcttccctgt ctctatcatg tggccaatgg gactcagctg 11761 ggctctatca cagcacagag gcacagaggg acctgcactt ggacctttct cctcctgggg 11821 cagggcctgc ctgatgctag ggacccagtg atgccatgtg tgccctccag atggcgttta 11881 gcatggctgt agtaatgctg gaaccatacc ccagggcaga atgggagttt gatgggtgtg 11941 gggatggtga tttgggaggt gggaggggcg agtcagactg cagtggcctt tagagctgtc 12001 cctctggcta tgcccactct caattgatgg atctgtcagt ggatgagagg ggacaagtgg 12061 gaggcatggc ttcagggaag agctgtatat atcctcaagg gcctaggccc tgtttagcct 12121 actgttgacc ttctcagcag cctgaccaag gggcccaggt ggcctgtcac agaactcatc 12181 ttcagggctc agttgcatcc ccttcccagt aagaatgtag gctcctgaca tgatcgtgtt 12241 ttctattaca gacggaggtt ggagtgccaa tgaagtatct cttttgtcgt attttctggt 12301 tattgttttg gtctttgttt catttcatct ttgggaagac ttcatctgga tagcccagag 12361 tgtcttggat attgccatcc tcctgcctta gcgctggcat gactgcagcg taggcctgtt 12421 atgctctgcc tcccctccat cctcaagtgg acaagaactg ggcatgtgtt ttcctgtgag 12481 cccagtggga cctgtccagg aggctccaga gtcaggggca tgtcctgctc tgctacaggg 12541 ccttgaccca gagaagacag gaaggtgccc aaagcccaag agagggaggg tccaacctgt 12601 gatcagactc caggcttctg tcccctgtcc tcaacccctg cacagacagc ctttctcaca 12661 gcatgcttta tctgtcttgt cccccaacag tgttctctgg gagacaagag attcagaagg 12721 agaatatgat ggtttgtata tggttggccc agggaatggc actgttagga gatgtggcca 12781 tgttggaatg ggtgtggcct tgtgggtgtg ggctttctct tgtcttagct gcctggaagt 12841 cagtatgctg ctagcagcct tcaaatgaag atgtagaact ctcagctcct cctgcaccat 12901 gcctgcctgg acgttgccat gctcttgcct tggtgataat ggactgaact tctgaacctg 12961 taagccaacc ccaattaaat gttgttttta taaaaattgc cttggtcatg gtgtctgttc 13021 acagcagtaa aaccctaaga cagggaggga ggaactcaag cttgaattgc atatgttcgc 13081 acgtcgggag gttctgtata tcaataacaa caaaccacag caagccatga gtgtgtgtgt 13141 atgtgtgtgg gtgtgggtct ctctttgtgt ctgtacctgt gtgtgtataa ggatgtgtgt 13201 gtgtatctct gtgtctgcat ttgtgtataa gaatgtgtgt gtatctgtgc atgtgtgtgt 13261 atgtggaatt gtgtgtgttt gtatctctct gtgtctgcat gtgtgtgtag gagggtgtat 13321 gtgtgtgcat ctgtgtatgt atatgtgttt gtctttctgt gtgtgtgtct ctgtgtgtgt 13381 gtgtctgcag attcatggtc aagtagctgc acttattaca ttctccatgt gggtcccagc 13441 accaagtcct cagtggtgga cagagcagaa ccaaactgat acaacttttg atgtcaggta 13501 gcctgggatc cttccaggtc tcttcttgca cataaacttg agacaggaat tcttagttcc 13561 ttctgtgttc ccaagcaaca ataatttctc ttgggaacaa ccccctttta gctatcttaa 13621 agcacatagt gtcttttcct ggtctgtttt gttttgctct ctctttctgg cttagagtca 13681 gatgaccgtt tgatctgaga tagagatttg aggagactaa acaggctgct taggttggga 13741 gaggagggtc ataatccaac tccagagcca gctttataat aatgctgaac agcataaaat 13801 aatgcttcag tgttattcat gcccaaaaga cagcatagct gagtacctgc aaaatggact 13861 caaggactgc agggagtgac tagagcaaac agagatcaaa ggacactcaa agatctgaga 13921 tttagcagga cttaaacatc agg // (SEQ ID 21) LOCUS AY055829  1695 bp mRNA linear ROD 25-JUN-2002 DEFINITION Mus musculus 2′-5′olygoadenylate synthetase 1D (Oas1d) mRNA, complete cds. ACCESSION AY055829 translation = “MARELFRTPIWRLDKFIEDQLLPDTTFLTELRADIDSISAFLME RCFQGAAHPVRVSRVVMGGCYNEYTVLKGRSEANMVVFLINLTSFEDQFNGQVVFIEE IWRHLLQLQQEKLCKLKFEVQSPKEPNSRFLSFKLSCPERQHELEFDVQPAYDALYEV RHFKPFDSSNYNKVYAQLTHECTTLEKEGEFSICFTDLHQSFLRYRAPKLWNLIRLVK HWYQLCKEKLRGPLPPQYALELLTVYVWEYGIHENPGLHTAQCFRTVLELVTKYKRLR IYWTWCYDFQHEISDYLQGQIKKARPLILDPADPTRNVAGSDLQAWDLLAKEAQIWID STFFTNHDMSIVEAWEVMPERQECVFL” BASE COUNT 438 a 432 c 432 g 393 t ORIGIN 1 gcagtcagca aacactcctg gcctcaggat ggcgagggaa ctcttcagaa ccccaatctg 61 gaggctggat aagttcatag aggatcaact ccttcctgac accaccttcc ttactgagct 121 cagagcagac atcgactcca taagtgcttt cctgatggag agatgcttcc agggtgccgc 181 ccatcctgtg agggtctcca gggttgtgat gggtggctgc tacaatgaat acactgtgct 241 caagggcagg tctgaggcca acatggtggt gttccttatc aatctcacaa gctttgagga 301 tcagttcaac ggacaggtag tgttcattga ggaaatttgg agacacctac tccagttgca 361 gcaagagaaa ctatgtaaac tcaagtttga ggtccagagc ccaaaggagc ccaactccag 421 gtttctgagc ttcaagctga gctgccccga gcgccagcat gagttggaat ttgatgtgca 481 gccagcctat gatgccctgt atgaagtaag acacttcaag ccctttgact ccagtaacta 541 caacaaagtc tacgcccaac tcacccatga gtgcaccaca ctggagaagg agggcgagtt 601 ctccatctgc ttcaccgacc tccatcagag cttcctgagg tatcgtgcgc ccaagctctg 661 gaacctcatc cgtttggtca agcactggta tcaactgtgt aaggagaagc tgagggggcc 721 gctgcctcca cagtacgccc tggagctgct cacagtctac gtctgggaat acgggatcca 781 cgaaaaccct ggactccata cagcccagtg cttccgcact gtcttagaac ttgtcaccaa 841 gtacaaacgg cttcgaatct actggacatg gtgttatgac tttcaacacg agatctctga 901 ctacctgcag ggacagatca aaaaagccag gcctctgatc ctggatccag cagacccaac 961 aaggaatgtg gctggttcag acttacaggc atgggacctg ctggcaaagg aggctcagat 1021 ctggatagat tcgactttct ttacgaacca tgatatgtcc attgtggaag cctgggaagt 1081 gatgccagag agacaagaat gtgtcttcct gtgagcaccc ccagcatctg cctaggagac 1141 tccagagtca ggggcatgtc ctcctcttct gtaagacctt gacctagaga ggacagacag 1201 gatggcactc aaggctccag cgaggggcat ccaacctgtg atcagactcc aggcttctga 1261 tccctgcctg cccatggaca gccttcctca caggctgctt cgtctgcctt agcttccaac 1321 agtgttctct gggagtcaga ctgtgatgga cagagaagaa cgcaagctcg acttccatct 1381 gttcacctgt tgggaggtta tgtccaatag tggctgatca tcatcaacaa accacagcaa 1441 gccatgaggg ggggtgcact ctgagggagg agtcctcaga ccacacagaa acttttcagc 1501 agtgcatgtg gccctggagc cctgggaatc tggccagtgt tcatcaaggt gcactgtttc 1561 tgcaacatgc aggctgggtt tatggtagtg caggaaaata aaattgcatg cattttaaaa 1621 tttatgattt taaaacttag gggtgtgtgt gtatgagatt tgaagcacta aattaaagca 1681 aaacgcattg aatta // (SEQ ID 22) LOCUS AY055830  1336 bp mRNA linear ROD 25-JUN-2002 DEFINITION Mus musculus 2′-5′olygoadenylate synthetase 1E, 45 kD isoform (Oas1e) mRNA, complete cds; alternatively spliced. ACCESSION AY055830 /translation = “MARELFRTPIWRLDNFIEDQLLPDTTFLTELRADIDSISAFLKE RCFQGATHPMRVSRVVMGGSYDEHNALKGRSEANMVVFFNDLTSFEDQLKWQQVFIEE IRKHLLQLQQEKPCKLKFEVQSSEEPNTRSLTFKLCSPERQQEVEFDVQPAYDALYEG GYCKSFESINYNKVYAQLIHECTTLEKEGEFSICFTDLHQSFLRYRAPKLWNLIRLVK HWYQLCKEKLRGPLPPQYALELLTVYVWEFGVQDSFGLHAAQCFRTVLELVTKYKCLL IYWTWFYDFRPEISDYLHGQIKKARPLILDPADPTRNVAGSDLQAWDLLAKEAQTWIH SNFFRNCDMSLVNGWEVSLPTVFSGSQAVMDREERKLDFHLSTCWEVLSNSG” BASE COUNT 335 a 342 c 349 g 310 t ORIGIN 1 tcaggatggc gagggaactc ttcagaaccc caatctggag gctggataac ttcatagagg 61 atcaactcct tcctgacacc accttcctta ctgagctcag agcagacatc gactccataa 121 gtgctttcct gaaggagaga tgcttccaag gtgccaccca ccctatgagg gtctccaggg 181 ttgtgatggg aggctcctat gatgaacaca atgcactcaa gggaaggtca gaggccaaca 241 tggtggtgtt ctttaatgat ctcaccagct ttgaggacca gttaaagtgg cagcaagtgt 301 tcattgaaga aattcggaaa cacctgctcc agttgcagca agagaagcca tgtaaactca 361 agtttgaggt gcagagctca gaggagccca acaccaggtc tctgaccttc aagctgtgct 421 cccccgagcg ccagcaggag gtggaatttg atgtgcagcc agcctatgat gctctgtatg 481 aagggggata ctgcaagtcc tttgaatcca ttaactacaa caaagtctac gcccaactca 541 tccatgagtg caccaccctg gagaaggagg gcgagttctc catctgcttc accgaccttc 601 atcagagctt cctgaggtat cgtgcgccca agctctggaa cctcatccgt ctggtcaagc 661 actggtatca actgtgtaag gagaagctga ggggaccgct gcctccacag tatgccctgg 721 agctgctcac agtctacgtc tgggaatttg gggtccaaga cagctttgga ctccatgcag 781 cccagtgctt ccgaacggtc ttagaactgg tcaccaagta caaatgcctt ctaatctact 841 ggacatggtt ttatgacttt cgacctgaga tctctgacta cctgcacgga cagatcaaaa 901 aagccaggcc tctgatcctg gatccggcag acccaacaag gaacgtggct ggttcagact 961 tacaggcatg ggacctgctg gcaaaggagg ctcagacctg gatacattca aattttttta 1021 ggaactgtga tatgtccctt gtgaatggct gggaagtgtc gcttccaaca gtgttctctg 1081 ggagtcaggc tgtgatggac agagaagaac gcaagctcga cttccatctg tccacctgtt 1141 gggaggttct gtccaatagt ggctgatcgt catcatcaaa tcacagcaag ccatggggga 1201 gggtgcactc tgagggagtc ctcagaccac acagaaactt ttcagcagtg catgtggccc 1261 tggcaccctg ggaatctggc cagtgttcat caaggtgcac tgtttctaca acatgcaggc 1321 cgggtttatg gcagtt // (SEQ ID 23) LOCUS AY055831  1559 bp mRNA linear ROD 25-JUN-2002 DEFINITION Mus musculus 2′-5′olygoadenylate synthetase 1E, 42 kD isoform (Oas1e) mRNA, complete cds; alternatively spliced. ACCESSION AY055831 translation = “MARELFRTPIWRLDNFIEDQLLPDTTFLTELRADIDSISAFLKE RCFQGATHPMRVSRVVMGGSYDEHNALKGRSEANMVVFFNDLTSFEDQLKWQQVFIEE IRKHLLQLQQEKPCKLKFEVQSSEEPNTRSLTFKLCSPERQQEVEFDVQPAYDALYEG GYCKSFESINYNKVYAQLIHECTTLEKEGEFSICFTDLHQSFLRYRAPKLWNLIRLVK HWYQLCKEKLRGPLPPQYALELLTVYVWEFGVQDSFGLHAAQCFRTVLELVTKYKCLL IYWTWFYDFRPEISDYLHGQIKKARPLILDPADPTRNVAGSDLQAWDLLAKEAQTWIH SNFFRNCDMSLVNGWEVSPEKQ” BASE COUNT 385 a 403 c 405 g 366 t ORIGIN 1 tcaggatggc gagggaactc ttcagaaccc caatctggag gctggataac ttcatagagg 61 atcaactcct tcctgacacc accttcctta ctgagctcag agcagacatc gactccataa 121 gtgctttcct gaaggagaga tgcttccaag gtgccaccca ccctatgagg gtctccaggg 181 ttgtgatggg aggctcctat gatgaacaca atgcactcaa gggaaggtca gaggccaaca 241 tggtggtgtt ctttaatgat ctcaccagct ttgaggacca gttaaagtgg cagcaagtgt 301 tcattgaaga aattcggaaa cacctgctcc agttgcagca agagaagcca tgtaaactca 361 agtttgaggt gcagagctca gaggagccca acaccaggtc tctgaccttc aagctgtgct 421 cccccgagcg ccagcaggag gtggaatttg atgtgcagcc agcctatgat gctctgtatg 481 aagggggata ctgcaagtcc tttgaatcca ttaactacaa caaagtctac gcccaactca 541 tccatgagtg caccaccctg gagaaggagg gcgagttctc catctgcttc accgaccttc 601 atcagagctt cctgaggtat cgtgcgccca agctctggaa cctcatccgt ctggtcaagc 661 actggtatca actgtgtaag gagaagctga ggggaccgct gcctccacag tatgccctgg 721 agctgctcac agtctacgtc tgggaatttg gggtccaaga cagctttgga ctccatgcag 781 cccagtgctt ccgaacggtc ttagaactgg tcaccaagta caaatgcctt ctaatctact 841 ggacatggtt ttatgacttt cgacctgaga tctctgacta cctgcacgga cagatcaaaa 901 aagccaggcc tctgatcctg gatccggcag acccaacaag gaacgtggct ggttcagact 961 tacaggcatg ggacctgctg gcaaaggagg ctcagacctg gatacattca aattttttta 1021 ggaactgtga tatgtccctt gtgaatggct gggaagtgtc gccagagaaa caataatgtg 1081 tcttccagtg agcagtgtag cacttgccta gaaggctcca gagtcaggat catgtgctcc 1141 tccgctgtaa gactttgacc tagagaggac aggatggtgc tcatgtctcc agcgaggggt 1201 atccaacctg tgattagact ccaggcttct gatccctgcc tgcccatgga tagccttcct 1261 cacaggctgc ttcatctgcc ttagcttcca acagtgttct ctgggagtca ggctgtgatg 1321 gacagagaag aacgcaagct cgacttccat ctgtccacct gttgggaggt tctgtccaat 1381 agtggctgat cgtcatcatc aaatcacagc aagccatggg ggagggtgca ctctgaggga 1441 gtcctcagac cacacagaaa cttttcagca gtgcatgtgg ccctggcacc ctgggaatct 1501 ggccagtgtt catcaaggtg cactgtttct acaacatgca ggccgggttt atggcagtt // (SEQ ID 24) LOCUS AY057107  2041 bp mRNA linear ROD 25-JUN-2002 DEFINITION Mus musculus 2′-5′olygoadenylate synthetase-like 1 (Oasl1) mRNA, complete cds. ACCESSION AY057107 /translation = “MAVAQELYGFPASKLDSFVAQWLQPTREWKEEVLETVQTVEQFL RQENFREDRGPARDVRVLKVLKVGCFGNGTVLRSTTDVELVVFLSCFHSFQEEAKHHQ AVLRLIQKRMYYCQELMDLGLSNLSVTNRVPSSLIFTIQTRETWETITVTVVPAYRAL GPSCPSSEVYANLIKANGYPGNFSPSFSELQRNFVKHRPTKLKSLLRLVKHWYQQYVR DKCPRANLPPLYALELLTVYAWEAGTREDANFRLDEGLATVMELLQDHELLCIYWTKH YTLQHPVIEACVRRQLRGQRPIILDPADPTNNVAEGYRWDIVAQRANQCLKQDCCYDN RDSPVPSWRVKRAPDIQVTVQEWGHSDLTFWVNPYEPIKKLKEKIQLSQGYLGLQRLS FQEPGGERQLIRSHCTLAYYGIFCDTHICLLDTISPEIQVFVKNPDGRSHAYAIHPLD YVLNLKQQIEDRQGLRCQEQRLEFQGHILEDWFDFKSYGIQDSVTVILSKTTEGAAPFVPS” polyA_signal 2013 . . . 2018 /gene = “Oasl1” BASE COUNT 469 a 591 c 551 g 430 t ORIGIN 1 gtgtagccat ggcagtcgcc caggagctgt acggcttccc ggcctccaag ctggactcct 61 ttgtggctca gtggctgcag ccaaccagag agtggaaaga agaggtcctg gagaccgtgc 121 agacagtgga gcagttcctg aggcaggaga atttccgtga agatcgtggc ccggctcggg 181 atgtgcgcgt gctcaaggta ctcaaggtag gctgctttgg gaatggcacc gtgctcagga 241 gcactacaga cgtggagctg gtcgtgttcc tgagctgttt ccacagcttc caggaagaag 301 ccaagcacca tcaggctgtc ctgagactga tacagaaaag gatgtactac tgccaggagc 361 tgatggacct tgggctcagt aacctgagtg tgactaacag agtacccagt agtctcatct 421 tcacgatcca gaccagggag acctgggaga ccatcactgt caccgttgtg cccgcctaca 481 gagccctggg cccttcctgt cccagctccg aggtctacgc aaatctgatc aaggctaatg 541 ggtacccagg aaatttctct ccatccttca gcgagctgca gcgaaacttc gtgaagcatc 601 ggccgacgaa gctgaagagc ctccttcggt tggtcaaaca ctggtaccag cagtatgtga 661 gagacaagtg cccccgggcc aacctgcccc ctctctatgc cctggagctg ctcactgtct 721 atgcctggga agcgggcacc cgggaggatg ccaacttcag gctggatgaa ggcctcgcca 781 cggtgatgga gctgctccag gatcatgagc tcctctgtat ctactggacc aagcactaca 841 cgctgcagca cccggtcatc gaggcctgtg tcaggagaca gctcagggga caaaggccta 901 tcatcctgga cccagcagac cccaccaaca atgtggcaga aggctacaga tgggacatag 961 tggctcagcg ggccaaccag tgtctgaaac aggactgttg ctatgacaac agggacagcc 1021 ccgtccccag ctggagggtg aagagagcac ccgatatcca ggtgaccgtg caggagtggg 1081 ggcactcgga tttaaccttc tgggtgaacc cttatgaacc cataaagaaa ctgaaagaga 1141 aaatccaact gagccagggc tacttgggcc tgcagcgtct gtcctttcag gagcccggcg 1201 gagaacgtca gctcatcaga agccattgca cgctcgccta ctacggaatc ttctgcgaca 1261 cccacatctg cctgctggac accatctccc ctgagatcca ggtctttgtg aaaaacccgg 1321 atggcaggag ccacgcctat gcgatccacc cgcttgatta tgtcctgaac ctgaagcagc 1381 agatagaaga caggcagggc cttcgatgcc aggagcagcg cctggagttc cagggccaca 1441 tcctggagga ctggtttgac tttaaatcct atggcatcca agacagtgtc acagtcatcc 1501 tgtccaagac gacggagggg gcagctccat ttgtgcccag ctagcttcct ctgtcggtgg 1561 ctctgcctgt tttattgtct catcctagac tcagcctagt tgcctctcct tcccgtcctc 1621 tgcccggatg gtccacgtct tcagtacctt gccagcaggg agtcagaggg ggtgtgagaa 1681 gtcgtgtaca gccagacact cttgtgtgac aatggaattc tgcagtcccc tgggaagtca 1741 tgccaggacc tctgccttcc tcgtggcctc actgtcaaga ctgtgtcagt gaatagctgg 1801 cctcacagac tattctcaca tgttcagaga aagccaaacc atcttcctaa ccaattacag 1861 ggaccctgct tgaggttgtc ccacctccaa attcttccca gtgacctcca tcagggcggc 1921 tctgaagcct tcccctgtgt ccccaaccac ttctgcctgc cttcgactat ccaaggcaag 1981 gtaggagggg atcaagttcc tttcaaatgg agaataaaaa agccattgtt tcttcccaga 2041 t // (SEQ ID 25) LOCUS AY196696  1442 bp mRNA linear ROD 20-MAY-2003 DEFINITION Rattus norvegicus 2′-5′ oligoadenylate synthetase 1A mRNA, complete cds. ACCESSION AY196696 translation = “MEKDLKSTPASELDKFIQDHLLPDTTFRDEVRADIDFICTFLKE KCFHGAALKVSKVVKGGSSGKGTTLQGKSDADLVVFLNNLTSFEDQLKRRGEVIEKIR KHLCQLQQEKQFKLKFEFQTPEQANSRSLSFKLSSPQLQHVVKFDVLPAYDVLGHVNI NSKPNAQIYASLIRKCTDLNKEGAFSTCFTELQRNFLKRRPTKLKSLIRLVKHWYQLC KEKLGDSLPPQYALELLTVHAWERGNGLTEFNTAQGFRTVLELVTKYQQLRIYWTMYY DFQHLDVSKYLYRQLKKPRPVILDPADPTGNVAGGNQEGWRRLASEARLWLQCPCFMN RDGSPVSSWEVQTEVPVCF” BASE COUNT 366 a 380 c 387 g 309 t ORIGIN 1 gctatggata taagggcagc caactccaga ggcaaggctg cagtcagcaa acatttgtgg 61 cctcaggatg gagaaggatc tcaagagtac tccagcctcg gagctggaca agttcataca 121 ggatcacctt cttcctgaca ccacattccg tgatgaggtt agagcagaca ttgacttcat 181 atgtactttc ctgaaggaga aatgcttcca cggtgccgcc ttgaaggtct ctaaggttgt 241 gaagggtggc tcctcaggca aaggaaccac gctacagggc aagtcagatg cagacctggt 301 ggtgttcctt aacaatctca ccagctttga ggatcagtta aagcgacggg gagaggtcat 361 tgagaaaatt cggaaacacc tgtgccagtt gcagcaagag aaacagttta aactgaagtt 421 tgagttccag accccagagc aggccaactc caggtctctg agcttcaagc tgagctcgcc 481 ccagctccag catgtggtga agtttgatgt gctaccagcc tatgatgtcc tgggtcatgt 541 taacatcaac agcaagccta acgcccaaat ctatgccagt ctcatcagga agtgcaccga 601 cctgaataaa gagggcgcgt tttctacctg cttcacggag ctccagagga acttcctgaa 661 gcggcgccca accaagctga agagtctcat ccgcctggtc aagcactggt accaactgtg 721 taaggagaag ctgggggatt cgctgccccc acagtatgcc ctggagctgc tcacggtcca 781 tgcctgggaa cgtggaaatg gacttactga gttcaacaca gctcagggct tccggacagt 841 cttggaactg gtcacaaagt accagcagct tcgaatctac tggactatgt attatgactt 901 tcaacaccta gatgtctcca aatacctata cagacagctc aaaaaaccca ggcctgtgat 961 cctggaccct gctgacccaa cagggaacgt ggctggtggg aaccaagaag gctggcggcg 1021 gttggcctca gaggcgaggc tgtggctgca gtgcccatgt tttatgaaca gggatggttc 1081 cccagtgagc tcctgggaag tgcagacgga ggttcctgta tgtttctagc aggtggatga 1141 ggcctggtca tgcatcctgc tgtgaaccca gcagcaccag cccaggaggc tccggagtca 1201 ggggcacgtg ctgctctgct gcaggacctt gacacagtga gggagggccc cactcgggat 1261 cacagtccat gcttctgatg cccgcccgcc atgtttgaat actgtccaat cacagatagc 1321 cttcctcaac agattcagaa ggggcggaaa gaactcaagc ttgacttcca tctgaccgtc 1381 cacctgttgg gaggttctgt ccaaccatgt ctgtcaacaa caataaagta caccaggtgc 1441 ca // (SEQ ID 26) LOCUS AY196697  1680 bp mRNA linear ROD 20-MAY-2003 DEFINITION Rattus norvegicus 2′-5′ oligoadenylate synthetase 1D mRNA, complete cds. ACCESSION AY196697 translation = “MGHGLSSISASELDKFIEVYLLPNTSFGADVKLAINVVCDFLKE RCFRGAAHPVRVSKVVKGGSSGKGTTLKGKSDADLVVFLNNLTSFEDQLNRRGEFIKE IKKQLYEVQRERHFGVKFEVQSSWWPNPRALSFKLSAPHLQQEVEFDVLPAYDVLGHV SIYSMPDPQIYASLIRKCMYLGKEGEFSTCFTELQRNFLKRRPTKLKSLIRLVKYWYH LCKEKLGKPLPPQYALELLTVYAWERGNGFVDFETAQGFRAVLELIIKYQELRIYWTT YYNFQHQEVSNYLHTQLTRIRPVILDPADPTGNIAGSNPEGWRRLAGEAAAWLRYPCF KYKDGSPVCPWDVPMEVDVPYQEDHFFRNFCLFFLFLFLFIFWRVSCV” BASE COUNT 410 a 438 c 441 g 391 t ORIGIN 1 aggctgcaga agcaaatgct ccggaccaat catggggcac ggactcagca gtatctcagc 61 ctcggagctg gacaagttca tagaggttta cctccttcca aacaccagct ttggtgctga 121 cgtcaaatta gcgatcaatg tcgtgtgtga tttcctgaag gagagatgct tccgaggtgc 181 tgcccaccca gtgagggtct ccaaggtggt gaagggtggc tcctcaggca aaggcaccac 241 actcaagggc aagtcagacg ctgacctggt ggtgttcctt aacaatctca ccagctttga 301 ggatcagtta aacagacggg gagagttcat caaggaaatt aagaaacagc tgtatgaggt 361 tcaacgtgaa agacattttg gagtgaagtt tgaggtccag agttcatggt ggcccaaccc 421 ccgggctctg agcttcaagc tgagtgcacc acacctccaa caggaggtgg agtttgatgt 481 gcttccagcc tatgatgtcc taggtcatgt aagcatctac agcatgcctg acccccaaat 541 ctatgccagt ctcatcagga agtgcatgta cctggggaag gagggcgagt tctctacctg 601 cttcacggag ctccagagga acttcctgaa gcggcgccca accaagctga agagtctcat 661 ccgcctggtc aagtactggt accatctgtg taaggagaag ctggggaagc cgctgccccc 721 acagtacgcc ctggagctgc tcacggtcta tgcctgggag cgtggaaatg gatttgtcga 781 ttttgagaca gcccagggct tccgggcagt cttggaactg atcataaagt accaggagct 841 tagaatctac tggacaacct attataactt tcagcaccaa gaggtctcca actacctgca 901 cacacagctc acaagaatca ggcctgtgat cctggacccg gctgacccaa caggaaacat 961 tgctggttcg aacccagagg gctggaggcg actagcagga gaggctgctg cctggctgcg 1021 gtacccatgc tttaagtaca aggacggttc cccagtgtgt ccctgggatg tgccgatgga 1081 ggttgacgtg ccgtaccagg aggatcactt ttttcgtaat ttttgtctat tttttttgtt 1141 tttgttcctt ttcatatttt ggagggtttc ttgtgtatag tgcaggctct cgtgtatatc 1201 gtcatcctcc tgcctcggtg ctggcatgac tgcagagtcc gcctgatgtg ccctggattc 1261 cctccatcct caagtggaca agactgtgca tctgtcgtcc tgtgagccca gcaggacctg 1321 cccaggaggc tccagagtca gtcatggctt tctgtgctgc aggcccttga cccagagagg 1381 gaaggaaggt tcccaagacc ccagtgaggg agggtccaac ctgtgatcag actctggtct 1441 tctgacccct gccttcctac tcctgcatcc tgtcccatca cagacagccc tcctcacagc 1501 ctgcttcatc tgccttgtcc tccaacagtg ctctcttggg agacaagaga ttcagaaggg 1561 gaggcaggaa ctcgagcttg acttccacct gtccacctgt tgggagttct gtccaatgtg 1621 tgaccaacga caataaacca tagcaagcaa aaaaaaaaaa aaaaaaaaaa aaaaaaaaaa // (SEQ ID 27) LOCUS AY196698  1712 bp mRNA linear ROD 20-MAY-2003 DEFINITION Rattus norvegicus 2′-5′ oligoadenylate synthetase 1C mRNA, complete cds. ACCESSION AY196698 translation = “MSRRLARTPIWRLDRFIEDHLLPDTTFLTEVRADIDSICAFLTE RCFQGATHPVRVSRIVKGGWFNKYTMLKGRSEATLVVFLNNLTCFEDQLKRREEFTEE IWKHLCQLQQEKQFKLNFEVQSTEQPDSRTLSIKLSSPQLQQEVEFDVQPAYDVLYEL RDKDDFNPDNYREIYARLIRESTTLEMEGEFSVCFTDLHQNFLKYRAPKLWNIIRLVK HWYQLCKKRLKYPLPPQYALELLTVYAWERGLEDRPALHTGHCFRSVLDLITEYKKLR IYWTWCYEFKKETFDYLSRQIKKDRPVILDPADPTRNVAGSNIQSWHVLAKEAAVWAR SSFFRNSDMTFVNGWKVSAQKQECVYQ” BASE COUNT 458 a 427 c 452 g 375 t ORIGIN 1 gcagtcagca cacattcctg acctcaggat gtcgaggcga ctcgccagaa ccccaatctg 61 gaggctggac agattcatag aggatcacct ccttcctgac accaccttcc ttactgaggt 121 cagagcagac attgactcta tatgtgcttt cctgactgag agatgcttcc aaggtgccac 181 ccaccctgtg agggtctcta ggattgtgaa gggtggctgg ttcaataaat acaccatgct 241 taagggaagg tcagaggcca ccctggtggt gttccttaac aatctcacct gctttgagga 301 tcagttaaag cgacgagaag agttcactga ggaaatttgg aaacacctgt gccagttgca 361 gcaagagaaa cagtttaaac tgaattttga ggtccagagc acagaacagc ccgactccag 421 gactctgagc atcaagctga gctcgcccca gctccagcag gaggtggagt ttgatgtgca 481 gccagcctat gatgtcctgt atgagctaag agacaaggac gactttaacc cggataacta 541 cagggaaatc tatgcccgcc ttatccgtga gagcaccacc ctggagatgg agggcgagtt 601 ctccgtctgc ttcacggacc ttcatcagaa cttcctgaag tatcgtgcac ccaagctgtg 661 gaatatcatc cgtctggtca agcactggta tcaactgtgt aagaagaggc tgaagtatcc 721 gctgccccca cagtacgccc tggagctgct cacggtctat gcctgggagc gtgggctgga 781 agaccgccct gcactacata caggccactg tttccgaagt gtcttagatc tgatcacaga 841 gtacaagaag cttcgaatct actggacatg gtgctatgaa ttcaaaaaag agacctttga 901 ctatctgagc agacagataa aaaaagacag gcccgtgatc ctggaccctg ctgacccaac 961 aaggaacgtg gctggttcaa acatccaatc ctggcacgtg ctggcaaaag aagctgcggt 1021 ctgggcgcgg tcgtctttct ttaggaacag tgatatgacc tttgtcaatg gctggaaagt 1081 gtcggcacag aaacaagaat gtgtctacca gtgagcacca cagcccttgc ccaggaggct 1141 tctgaagtca gggccatatg ctcttctgct gcaagacctt gtcctgaaga gaacagtttg 1201 gcgcaccagg gtccagtgag gggcatccaa cctgtgatca gactccaggc ttctattccg 1261 tcctgcccat gggacagcct tcctcacagc ctgcttcacc tgccttatcc cccacagtgt 1321 tctttgggag tcagactccg aaggaaagag aagagctcaa acgtggcttc tgtctgtcca 1381 cctgtgggga ggctctgtcc acaaacatgt ctgatcatga acaatcgacc acagcaatcc 1441 ctgagggagt gtgcactcgg aggggtgagt cctcagccca cataggaacg gctcagcaga 1501 ggagcgtggc ccgggaacgc tggggatctg gccagtgtgc atcgaggtgc actgttgggc 1561 aaagtgtgag ctggggttac ggcagtgcag ggaaataaaa ttgtatgcac tttaaaactt 1621 aggaccttaa aacttagatg tgtgtgcgtg tgaggatgag atttgaagcc ctgaattaaa 1681 gtaaaatgca aaaaaaaaaa aaaaaaaaaa aa // (SEQ ID 28) LOCUS AY196699  1518 bp mRNA linear ROD 20-MAY-2003 DEFINITION Rattus norvegicus 2′-5′ oligoadenylate synthetase 1E mRNA, complete cds. ACCESSION AY196699 translation = “MPWKLANTPIWRLDRFIQDHLLPDTTFLTEVRADIDFICAFLTE RCFQGATHPVRVSRIVMGGCYDEYSMLKGRSEATLVVFLNNLTCFEDQLKRREEFIEE IWKHLCQLQQEKQFKLNFEFQTSEQANSRSLSIKLSSPQLQQEVEFDVQPAYDVLYAW RYNKYLDPRIYNKIYASLIRESTNLDKEGEFSVCFTELQQHFLKHPGHKMWNLIRLVK YWYQLWKEKLGDLLPPQYALELLTVHAWELGIENTCELYIARGFRSVLELIIKYRCLL IFWTLCYDFNHNEVSEYLNKQLQKDRPVILDPADPTRNVAGSNLQAWHLLAEEAGAWV QSSFFRNSDMSLVHSWKVPPEKQTCVIL” BASE COUNT 375 a 404 c 382 g 357 t ORIGIN 1 tcaggatgcc gtggaaactt gccaataccc ccatctggag gctggacaga ttcatacagg 61 atcacctcct tcctgacacc accttcctta ctgaggtcag agcagacatt gactttatat 121 gtgctttcct gactgagaga tgcttccaag gtgccaccca ccctgtgagg gtctctagga 181 ttgtgatggg cggctgctac gatgaatact ccatgctcaa gggaaggtca gaggccaccc 241 tggtggtgtt ccttaacaat ctcacctgct ttgaggatca gttaaagcga cgagaagagt 301 tcattgagga aatttggaaa cacctgtgcc agttgcagca agagaaacag tttaaactga 361 attttgagtt ccagacctca gagcaggcca actccaggtc tctgagcatc aagctgagct 421 cgccccagct ccagcaggag gtggagtttg atgtgcagcc agcctatgat gtcctgtatg 481 cttggagata caacaagtac cttgatccca gaatctacaa caaaatctac gccagcctca 541 tccgtgagag caccaacctg gataaggagg gcgagttctc cgtctgcttc acagagctcc 601 aacaacactt cctgaagcat cctggacata agatgtggaa tctcatccgc ctggtcaagt 661 actggtatca actgtggaag gagaagctgg gggatttgct gcccccacag tacgccctgg 721 agctgctcac ggtccatgcc tgggaactgg ggattgaaaa cacctgtgag ctatacatag 781 cccggggctt ccgaagtgtc ttagaactga tcatcaaata tcggtgtctc ctaatcttct 841 ggacattgtg ttatgacttt aatcacaatg aggtctctga gtacctgaac aaacaactcc 901 aaaaagacag gcccgtgatc ctggaccctg ctgacccaac aaggaacgtg gctggttcaa 961 acctccaggc ctggcacctg ctggcagaag aggctggggc ctgggtgcag tcgtctttct 1021 ttaggaacag cgatatgtcc cttgttcaca gttggaaagt gccgccagag aaacaaacat 1081 gtgtcatcct gtgagcccag caggacctgc ccaagaggct tcggagtcag ggccatgtgc 1141 tcttctgctg caagaccttg ccctggagag aacagttcgg tgcaccaggc tccagtaagg 1201 ggcatccaac ctgtgatcag actccaggct tctgatcccg tcctgccctg cccagggaca 1261 gccttcctca cagcctgctt cacccgcctt atcccccaca gtgttctctg ggagtcggac 1321 tctgaaggaa agggacaaac ttaaccttga cttccacctt ttcacctgtt gtgaagctca 1381 gtccaacaat gtctgattat ctatgataag ccacagcaag ccattgcggg ggggtgtgca 1441 ctctgaggga tggggcctta gaagtacgtg tatgactttt catgctctac tagaaacatt 1501 gagtacttgt tgcaagct // (SEQ ID 29) LOCUS AY196700  1619 bp mRNA linear ROD 20-MAY-2003 DEFINITION Rattus norvegicus 2′-5′ oligoadenylate synthetase 1F mRNA, complete cds. ACCESSION AY196700 /translation = “MVNLSSTPACELDRFIKDHLPADTSFHAELRADIDFICAFLKER CFQGAAHPVRVSRVVMGEHTMLKGRSEANLVVFLNDLPSFEDQLNLQGEFIEEIRKRL CQLQQEKTLQVKLEVQSSEQPSSKSLSFTLSSPQLQQEVEFDVQPAYDVLFALRNNHK PDPQIYTKTYAYLISVCTTLKKEGEFSTCFMELRQNFLKHREPKLKSLIRLVKHWYQL CKEKLGKPLPPQYALELLTVYAWESGSRDCEFNTAQGFRTVLELVTKYQWLRIYWTLY YDFRNKKVSDYLHKQLKKTRPVILDPADPTRNVAGSNPLCWRLLAKEAASWLQCPCFR TCDMSLVHSWEVLTKVEFPQECVLL” BASE COUNT 409 a 462 c 388 g 359 t 1 others ORIGIN 1 ggctgcagtc agcaaacact cccggcctta aaatggtgaa cctcagcagc accccagcct 61 gtgagctgga caggttcata aaggatcacc tccctgctga caccagcttc catgctgagc 121 tcagagcaga cattgacttc atatgtgctt tcctgaagga gagatgcttc caaggtgccg 181 ctcaccctgt gagggtctcc agggttgtga tgggcgaaca caccatgctt aagggtaggt 241 cagaagccaa cctagtggtg ttccttaacg atctccccag ctttgaggat cagttgaatc 301 tacagggaga gttcattgag gaaattcgga aacgactgtg tcagctgcag caagagaaaa 361 cgttacaagt gaagcttgag gtccagagct cagagcagcc cagctccaag tctctgagct 421 tcacgctgag ctcgccccag ctccagcagg aggtggagtt tgatgtgcag ccagcctatg 481 atgtcctgtt tgccctaaga aacaaccaca agcccgaccc ccaaatctac accaaaacct 541 acgcctacct catcagtgtg tgcaccactc tgaagaagga gggcgagttc tccacctgct 601 tcatggagct ccggcaaaac ttcctgaagc atcgggaacc caagctgaag agcctcatcc 661 gtctggtcaa gcactggtat caactgtgta aggagaagct ggggaagccg ctgcccccac 721 agtacgccct ggagctgctc acggtctatg cctgggaaag tgggagtaga gactgtgaat 781 tcaacacagc ccagggcttc cgaaccgtct tggaactggt caccaagtat cagtggcttc 841 gaatctactg gacattgtat tatgacttta gaaacaagaa ggtctctgat tacctacaca 901 aacagctcaa aaaaaccagg cctgtgatcc tggacccggc tgacccgaca agaaatgtgg 961 ctggttcaaa ccccctctgc tggcgactgt tggcaaaaga agctgctagc tggctgcagt 1021 gcccatgctt taggacctgt gatatgtccc tcgtgcactc ctgggaagtg ctgacaaagg 1081 tcgagtttcc acaggaatgt gtccttctat gagcaccaaa gcacctgccc aggatgctca 1141 agagtcaggg gcatgacctc tgctgcaggc ccttgaccta gagaggagag gaagctcccc 1201 aaaaccccaa caagggaggg tccaacctgt gatcagactc tggtcttctg acccctgcct 1261 tcctactcct gcatcctgtc ccatcacaga cagccctcct cacagcctgc ttcatctgcc 1321 ttgtcctcca acagtgctct cttgggagac aagagattca gaaggggagg caggaactcg 1381 agcttgactt ccacctgtcc acctgttggg agttctgtcc aatgtgtgac caacgacaat 1441 aaaccatagc aagccatgag gatatgtgaa cattctgaag gatgtgtgtt ctcctccctc 1501 tccctctccc cttccctacc taccctgtcc tgcctcacat acgttttctt acctctacnt 1561 gcatatgaca tgatagtata tttaagtgat cccaaaagtt ccaccagaga actactaaa // (SEQ ID 30) LOCUS AY221507  1469 bp mRNA linear ROD 02-JUN-2003 DEFINITION Rattus norvegicus 2′-5′ oligoadenylate synthetase 1G (Oas1g) mRNA, complete cds. ACCESSION AY221507 translation = “MEQELRSTPSWKLDKFIEVYLLPNTSFRDDVKSAINVLCDFLKE RCFRDTVHPVRVSKVVKGGSSGKGTTLKGKSDADLVVFLNNFTSFEDQLNRRGEFIKE IKKQLYEVQREKHFRVKFEVQSSWWPNPRALSFKLSAPHLQQEVEFDVLPAYDVLGHV SLYSNPDPKIYTILISECISLGKEGEFSTCFTELQRNFLKQRPTKLKSLIRLVKHWYQ LCKEKLGKPLPPQYALELLTVYAWERGNGITEFNTAQGFRTILELVTKYQQLRIYWTK YYDFQHPDVSKYLHRQLRKSRPVILDPADPTGNVAGGNQEGWRRLASEARLWLQYPCF MNRGGSPVSSWEVPTEVPVPSEQVDEAWSCILL” polyA_signal 1428 . . . 1433 /gene = “Oas1g” BASE COUNT 385 a 388 c 392 g 304 t ORIGIN 1 gttccaagtt caaccaggct gcgagacaca ggacctgcag gctgcagagg caaaagctcc 61 ggaggtcatg gagcaggaac tcaggagcac cccgtcctgg aagctggaca agttcataga 121 ggtttacctc cttccaaaca ccagcttccg tgatgatgtc aaatcagcta tcaatgtcct 181 gtgtgatttc ctgaaggaga gatgcttccg agatactgtc cacccagtga gggtctccaa 241 ggtggtgaag ggcggctcct caggcaaagg caccacactc aagggcaagt cagacgctga 301 cctggtggtg ttccttaaca atttcaccag ctttgaggat cagttaaaca gacggggaga 361 gttcatcaag gaaattaaga aacagctgta tgaggttcag cgtgaaaaac attttagagt 421 gaagtttgag gtccagagtt catggtggcc caacccccgg gctctgagct tcaagctgag 481 tgcaccacac ctccaacagg aggtggagtt tgatgtgctt ccagcctatg atgtcctagg 541 tcatgttagc ctctacagca atcctgatcc caagatctac accatcctca tctccgaatg 601 tatctccctg gggaaggagg gcgagttctc tacctgcttc acggagctcc agaggaactt 661 cctgaagcag cgcccaacca agctgaagag tctcatccgc ctggtcaagc actggtacca 721 actgtgtaag gagaagctgg ggaagccgct gcccccacag tacgccctgg agctgctcac 781 ggtctatgcc tgggaacgtg gaaatggaat tactgagttc aacacagctc agggcttccg 841 gacaatcttg gaactggtca caaagtacca gcagcttcga atctactgga caaagtatta 901 tgactttcaa cacccagatg tctccaaata cctacacaga cagctcagaa aatccaggcc 961 tgtgatcctg gaccctgctg acccaacagg gaacgtggct ggtgggaacc aagaaggctg 1021 gcggcggttg gcctcagagg cgaggctgtg gctgcagtac ccatgtttta tgaacagggg 1081 tggttcccca gtgagctcct gggaagtgcc gacagaggtt cctgtgcctt cagagcaggt 1141 ggatgaggcc tggtcatgca tcctgctgtg aacccagcag caccagccca ggaggctccg 1201 gagtcagggg cacgtgctgc tttgctgcag gaccttgaca cagtgaggga gggccccact 1261 cgggatcaca gtccatgctt ttgatgcccg cccgccatgt ttgaatactg tccaatcaca 1321 gacagccttc ctcaacagat tcagaagggg cggaaagaac tcaagcttga cttccatctg 1381 accgtccacc tgttgggagg ttctgtccaa ccatgtctgt caacaacaat aaagtacagc 1441 aggtgccaaa aaaaaaaaaa aaaaaaaaa // (SEQ ID 31) LOCUS AY196701  1701 bp mRNA linear ROD 20-MAY-2003 DEFINITION Rattus norvegicus 2′-5′ oligoadenylate synthetase 1H mRNA, complete cds. ACCESSION AY196701 translation = “MEKDLKSTPAWKLDKFIQNHLLADTTFVTEAKADIEFLCDFLTE RCFQDASHPVRVSRIVMGGCYDEYSMLKGRSEATLVVFFNNLTRFEDQLKRREELIEE IWKHLCQLQHEKQFKLKFEVQSSEQDNYSSLSIKLSSPQLQQEVEFDVQPAYDVLYEL KEKLELDCEFYNKIYARLIRECITLRKEGEFSVCFMELQQKFLWNRPEDLRNLLVLVK HWYQLCKEKLGDSLPPQYALELLTVHAWENEIPAKYGAQTARGFQSVLELIIKYTCLR VYWTFYYDILHQDVSSYLHKQLRKERPVILDPADPTRNVAGLNIDGWCELAKEAEAWL KYPCFRHIDETFVGSWEVPPEKQGGVFL” BASE COUNT 440 a 421 c 460 g 380 t ORIGIN 1 gcagtcagca aacattcctg gcctcaggat ggagaaggat ctcaagagta ctccagcttg 61 gaagctggac aagttcatac agaatcacct ccttgctgac accaccttcg ttactgaggc 121 caaggcagac atagagttcc tatgtgattt cctgactgag agatgcttcc aagatgcctc 181 ccaccctgtg agggtctcta ggattgtgat gggcggctgc tatgatgaat actccatgct 241 caagggaagg tcagaggcca ccctggtggt gttctttaac aatctcacca gatttgagga 301 tcagttaaag cgacgggaag agctcattga agaaatttgg aaacacctgt gccagttgca 361 gcacgagaaa cagtttaaac tgaagtttga ggtccagagc tcagagcagg acaactacag 421 ctctctgagc atcaagctga gctcgcccca gctccagcag gaggtggagt ttgatgtgca 481 gccagcctat gatgtcctgt atgaactgaa agaaaaactg gagcttgact gtgagttcta 541 caacaaaatc tatgcccggc tcatccgtga gtgcatcacc ctgaggaagg agggcgagtt 601 ctccgtctgc ttcatggagc tccagcaaaa gttcctgtgg aatcgtccag aagacctgag 661 gaatctcctc gtactggtca agcactggta tcaactgtgt aaggagaagc tgggggattc 721 gctgccccca cagtacgccc tggagctgct cacggtccat gcctgggaaa acgaaattcc 781 agccaaatat ggagcacaga cagctcgggg tttccagagt gtcttagaac tgatcattaa 841 gtacacctgt cttcgagtct actggacatt ttattacgac attctacacc aggatgtctc 901 cagctacctg cacaaacagc tccgtaaaga aaggcctgtg atcctggacc ctgctgaccc 961 aacaaggaac gtggctggtt tgaacataga tggctggtgt gagctggcaa aagaggcaga 1021 agcctggctg aagtacccgt gctttaggca catcgatgag acctttgtgg gctcctggga 1081 agtgccgcca gagaaacaag gaggtgtctt cctgtgagca ccacagccct tgcccaggag 1141 gctctggagt caggggcatt cactcctctg ctgcaagacc ttgtcctgca gagaacagtt 1201 tggtacacca ggctccagtg aggggcatcc aacctgtgat cagactctag gcttctgatc 1261 ccgtcctgcc catgggacag ccttcctcac agcctgcttc acctgcctta tcctccacag 1321 tgctctctgg gagtcagact ccgaaggaaa gagaagagct caaacttggc ttctgtctgt 1381 ccacctgtgg ggaggctctg tccacaaaca tgtctgatca tgaacaattg accacagcaa 1441 tccctgaggg agtgtgcact cggaggggtg agtcctcagc ccacatagga acggctcagc 1501 agaggagcgt ggcccggaac gctggggatc tggccagtgt gcatcaaggt gcactgttgg 1561 gcaaagtgtg agctggggtt acggcagtgc agggaaataa gattatgtac actttaaaac 1621 ttaggacctt aaaacgtatg tgtgtgcatg tgaggatgag atttgaagcc ctgaattaaa 1681 gtaaaatgca aaggactaaa c // (SEQ ID 32) LOCUS AY227756  1980 bp mRNA linear ROD 06-JUN-2003 DEFINITION Rattus norvegicus 2′-5′ oligoadenylate synthetase-like 1 protein (Oasl1) mRNA, complete cds. ACCESSION AY227756 /translation = “MAVAQELYSFPASKLDSFVAQWLQPTREWKEEVLETVQTVEQFL RQENFRGERGPAQDVRVLKVLKVGCFGNGTVLRSTTDVELVVFLSCFHSFQEEAKHHQ AVLRLIQKRMSYCRDLLDLGLSNLSVIEEVPSSLIFTIQTRETWEPITVTIVPAFRAL GPSCPNSAEVYVNLIKANGYPGNFSPSFSELQRSFVKHRPTKLKSLLRLVKHWYQQYV RDKCPRANLPPLYALELLTVYAWEAGTQEDSNFRLDEGLATVMELLQDHELLCIYWTK YYTLQHPVIERFVRRQLKGERPIILDPADPTHNVAQGYRWDIVAQRASQCLKQDCCYD DRDAPVPSWTVKRAPYIQVTVQQWGHPDLILWVNPYEPIKKLKEKIRLSRGYSGLQRL SFQEPGGQRQLIRSQCSLAYYGIFCDTQICLLDTISPEIQVFVKNPDGGSHAYAIHPL DFVLSLKQQIEDRQGLQSQEQQLEFQGRVLEDWFDFKSYGIQDSITIILSRKREGKAPSAPS” polyA_signal 1953 . . . 1958 /gene = “Oasl1” BASE COUNT 477 a 586 c 510 g 407 t ORIGIN 1 gcgcagacat ggcagtagcc caggagcttt acagcttccc agcctccaag ctggactcct 61 ttgtggctca gtggctgcag ccaaccagag aatggaagga ggaggtcctg gagacggtgc 121 agacagtgga gcagttcctg aggcaggaga acttccgtgg agaacgtggc ccggcccagg 181 atgtacgagt gctcaaggta ctcaaggtag gctgctttgg gaatggcaca gtactcagga 241 gtaccacaga cgtggagctg gtggtgttcc tgagctgttt ccacagcttc caggaagagg 301 ccaaacacca ccaggctgtt ctgagactga tacagaaaag gatgtcttac tgccgggacc 361 tgctggatct cgggctcagt aacctgagtg tgattgaaga agtgcccagt agtctcatct 421 tcactatcca gaccagggag acctgggagc ccatcactgt caccatcgtg cccgccttca 481 gagccctggg accttcctgt cccaactccg ccgaggtcta tgtgaatctg atcaaggcta 541 acggctaccc cggaaatttc tctccttcct tcagcgagct acagaggagc ttcgtgaagc 601 ataggccgac taagctgaag agcctcctac ggttggtcaa acactggtac cagcagtacg 661 tgagagacaa gtgcccccgg gccaacctgc cccccctcta tgccctggag ctgctaactg 721 tctacgcgtg ggaagcaggt acgcaggagg attcgaactt caggctggat gaaggtctcg 781 ccactgtcat ggagttgctc caggatcatg aactcctgtg catctactgg accaagtact 841 acaccctgca acacccagtc attgagcgct tcgtcaggag acagctcaaa ggagaaaggc 901 ccattatcct ggacccagca gaccccaccc acaacgtggc gcaaggctac aggtgggata 961 tagttgctca gcgcgccagc cagtgtctga aacaggactg ttgctatgac gacagggacg 1021 cccccgtccc cagctggact gtgaagagag caccatatat ccaggtgacc gtgcagcagt 1081 ggggtcaccc ggatttaatc ctctgggtga acccttatga acccataaag aagctgaaag 1141 agaaaatccg actgagccgg ggctactccg gcctgcagcg cctgtccttt caggagcccg 1201 gcggccaacg gcagctcatc agaagccaat gctcgcttgc ctactacgga atcttctgcg 1261 acactcagat ctgcctgctg gacaccatct cccccgagat ccaggtcttt gtgaaaaacc 1321 cggatggtgg aagccacgcc tacgccatcc acccacttga cttcgtcctg agcctgaagc 1381 agcagatcga agataggcag ggccttcaaa gccaggagca gcagctggag ttccagggcc 1441 gcgtcctgga agactggttt gactttaaat cctatggcat ccaagatagt atcacgatca 1501 tcctatccag gaagagggag gggaaagccc catctgcgcc cagctagctt cctctgcctc 1561 ttttgctatc tcatcctaaa gtcagcctag tcacccctcc ttccggtcct cagccgggat 1621 gatcccagca gggagccaga agggaatact gccagacgct cttgtgtgac aatgaaactc 1681 tgcagtcacc tgtgaaatca caccaggacc tctacgctct caagactggg tcagtgaatg 1741 gccgtcccac aaataaacta ttctcgcttg ttcttgggaa gccaaacgat cttcctaacc 1801 aatcaaatgg accctgcttc aggttgttcc cccacacaca ccagcaacct ccatcaggtt 1861 ggatctgaag ccttcccctg tgctcccaac cacttctgcc tgcctcagcc tatccaaggc 1921 aaggtagggt atcaagttcc tttcaaatgg agaataaaca acctttgttt cctcccagat // (SEQ ID 33) LOCUS AY237116  1750 bp mRNA linear ROD 12-JUN-2003 DEFINITION Rattus norvegicus 2′-5′ oligoadenylate synthetase 2-like protein (Oasl2) mRNA, complete cds. ACCESSION AY237116 /translation = “MDTLPDLYGTVGDSLDYFLEHSLQPQRDWKEEGKDAWERIERFF REKCFCDELLLDQEVRVLKVVKGGSSGKGTALNHRSDQDMILFLSCFSSFKQQARDRK AVIDFIKSKLIHCRKSLAYNITVRQHKEGKRTPRSLTLEIQSRKSNDIICMDILPAYN ALGSFSRDCKPEPEIYENLIRCKGYPGDFSPSFAELQRHFVKSRPVKLKNLLRLVKFW HLKYLRHKYRRAVLPSKYALELLTIYAWEMGTDSSDNFNLDEGFVAVMELLRDYQDIC IYWTKYYDFQNEVVRNFLKEQLKGDRPIILDPADPTNNLGRRGKWELVAKEATYCLLQ LCCVTADRWNVQVSIAHYLRGARDVQVTVKQTGREEWILLTNPHSPIRKLKAKIKKRM NLCGELRISFQEPGGERQPLSGRKTLSDYGIFSKVNIRVMETFPPEIQVFVRYPGGQN KPFAIDPDATILSLWEKIEEDGGPCTEDWVLLFEGEELDDDDNLAELQIKDCDTIQLSRVS” BASE COUNT 485 a 415 c 468 g 382 t ORIGIN 1 ttctcccagc attgctgagc agaagcacag aagattcaat ccagaggaca ggctgatcca 61 gcagagatgg atacattacc cgacctgtat gggaccgttg gggacagtct agactacttc 121 ctggaacaca gccttcagcc ccaaagggac tggaaagagg aaggaaagga tgcctgggag 181 agaattgaga ggttctttcg ggaaaagtgc ttctgtgatg agctgctcct ggaccaagaa 241 gtcagggtgc ttaaagtggt aaagggaggc tcctcaggaa aggggacggc gctgaaccac 301 agatctgacc aggacatgat tctgttcctg agctgttttt ccagtttcaa acagcaggca 361 agagaccgga aggccgtcat agacttcatt aagagcaagc tgattcattg taggaaaagc 421 ctggcctaca acatcactgt ccgtcaacac aaagaaggca aaaggacccc tcgctccctg 481 accctagaga tccagtccag gaagagcaat gacataattt gcatggatat tctccctgct 541 tacaatgcct tgggatcctt ttccagagac tgcaaaccag aacctgaaat ctacgagaat 601 ctgataaggt gtaagggcta ccctggcgac ttctcgccaa gtttcgcaga gttacagaga 661 cattttgtga aaagtcgccc ggttaaactg aaaaacctcc tacggttggt gaagttctgg 721 cacctgaagt acctgaggca taaatataga agagcagtgt tgccctcaaa atatgcactg 781 gagttgctga ccatctatgc ttgggagatg ggtacagaca gcagtgataa tttcaatctg 841 gatgaagggt ttgtagccgt catggagctc ctcagggact accaagacat ctgcatctac 901 tggaccaagt actatgattt ccaaaatgag gtcgtcagga acttcctgaa ggaacagctt 961 aagggcgacc ggcctatcat tctagaccca gctgacccca ccaacaacct aggaagaaga 1021 ggaaaatggg aactggtggc caaagaagct acttactgcc tgctacagtt gtgttgtgtg 1081 actgcagacc gctggaatgt tcaggtatct atcgcgcact acctccgagg agcgagggac 1141 gttcaggtga cagtgaaaca aacaggaagg gaagagtgga ttctcttgac aaacccccac 1201 agccccatca ggaagttgaa ggcaaagatc aagaagagaa tgaacctctg tggggagctg 1261 cgtatctcct tccaggagcc gggaggggag aggcagccgc tgagtggccg gaaaaccctg 1321 tcggattatg gaattttctc taaggtgaac atccgggtga tggagacctt tcctcctgag 1381 atccaggtct ttgtgaggta tcccggtggc cagaacaagc cttttgccat cgaccctgat 1441 gctaccatct taagcctgtg ggagaaaatt gaggaagatg gaggcccatg tacggaggat 1501 tgggtactac tgtttgaggg tgaggagctg gacgatgatg acaaccttgc agagcttcag 1561 atcaaggact gtgacaccat ccagctcagc agggtctcct agtctgcctc cccacatcac 1621 ccctttactc tgacatattc ctcctgtagc ttaaacatca tcatatccgg ttggggattt 1681 ggctcagtgg tagagcgctt gcctagcaac cgcaaggccc tgggttcggt ccccagctcc 1741 gaaaaaaaaa // (SEQ ID 34) LOCUS AY230746  2311 bp mRNA linear ROD 05-JUN-2003 DEFINITION Rattus norvegicus 2′-5′ oligoadenylate synthetase 2 (Oas2) mRNA, complete cds. ACCESSION AY230746 /translation = “MGNWMPGWSSSGSLGVPPMPVQKLEKSVQVNLEPDEKCLSQTEV SSVPSQKLEEYIQANLKPDEESLKQIDQAVDAISDLLCSEVMIDVLKVVKGGSYGRKT VLRDCSDGTLVLFTGLFKQFQDQKKYQDKLLDLIEQRLKSHEKYKKSVKRKLSLLEVQ VSIPGQSILLQLLPTFNPLCISENPSAQVYQNLKRSMDQVKASPGEFSDCFTTLQQRF FEKYPGRLKDLILLVKHWYKQLQDKWIIPSPPPLLYALELLTVYAWEQGCQTKDFDIT QGIRTVLQLISQPTNLCVYWLDNYNFEDETVRNNLLHQLNSPRPVILDPTDPTNNVGK DDRFWQLLAEEAQEWLNSLRLNKPHKPCWDVLPMPFFITPSHCLDKFIKDFLQPDKVF LNQIKRAVDIICSFLKETCFQNSDIKVLKIIKGGSTAKGTALQQRSDADIIVFLSSLD SYDSLETERSQYVQEIRKQLEACQKAFNLGVKFDISKWMAPRVLSFTLESKSLKQSVE FDVLPAYDALGQLRSDYTSRLKAYKKLIELYASQDSLKGGEFSVCFTELQRDFIETRP TKLKGLIRLIKMWYKQCERKMKPKASLPPKYALELLTVYAWEHGSGTDGFDTAEGFRT VLDLVIRYRQLCVFWTVNYNFEEDHMRKFLLTQIQKKRPVILDPADPTGDVGGGDRWC WHLLAKEAKEWLSSSCFQVEPKSPVQPWKVPVVQTPGSCGAQIYPVVGGVY” BASE COUNT 649 a 573 c 566 g 523 t ORIGIN 1 agtgctctgc ctctgtcatt cacaagccca gctagcaact atgggaaact ggatgcctgg 61 ctggtcatcc agtgggtctt tgggggtgcc ccccatgcca gtgcagaagc tagaaaagtc 121 tgtccaggta aaccttgaac cagatgaaaa atgtctgagt cagaccgagg tgtcctctgt 181 accatcccag aagctagaag aatatatcca ggcaaacctc aaacccgatg aagaatctct 241 gaagcagata gaccaggctg tggatgccat ctctgacctg ctgtgcagtg aggtgatgat 301 cgatgtgctg aaagtggtta agggtggctc ctatggtcgg aaaacagtcc taagagactg 361 ctccgatggt acacttgttc tcttcaccgg tctcttcaaa cagttccaag accagaagaa 421 ataccaagat aagctccttg acttgattga acaacggctg aaaagccatg agaaatacaa 481 gaagtcagta aaacgtaaac ttagcctcct tgaagtacaa gtgtctatac cagggcagag 541 tatactcttg cagttgcttc caaccttcaa tcctctgtgc atcagtgaga atcccagcgc 601 ccaggtctat cagaatctca aaagatccat ggatcaagta aaagcatcac ctggggaatt 661 ctcagactgc ttcaccacac tgcagcagag gtttttcgag aaatatcccg ggagactgaa 721 ggatttgatt ctattggtca agcactggta taaacagttg caggataagt ggataatacc 781 ctcacctccg ccattgctat atgcactgga gctgcttact gtgtatgcct gggaacaggg 841 ctgccagact aaagactttg acatcacgca aggtatcagg actgtgctgc aactcatcag 901 tcagccgaca aacctgtgtg tctactggtt agacaattac aactttgagg atgagacagt 961 ccggaacaac cttctgcacc agctcaactc cccaagaccg gtcatcttgg atccaaccga 1021 cccaaccaac aatgtgggca aagatgacag gttctggcag ctactggcag aagaggctca 1081 ggagtggctg aactctctca gactgaataa gccacacaaa ccatgttggg atgttctgcc 1141 catgccattt ttcatcaccc caagccactg cctggacaag ttcatcaaag acttcctcca 1201 acctgacaag gtcttcctaa accaaatcaa aagagctgtt gacattatct gttcattctt 1261 aaaagagacc tgcttccaga attctgacat caaagtcctg aagatcatca agggaggatc 1321 cactgccaaa ggcacagctc tgcagcagag atcagatgct gacatcatag tgttcctcag 1381 ctcactggat agttatgact ccctagaaac tgaacgctcc cagtacgtcc aggagatccg 1441 aaagcagtta gaagcctgcc agaaggcctt taatttaggg gtgaagtttg atatttccaa 1501 atggatggcc cccagggtgc tgagttttac cctggaatcc aagagtctca agcaaagtgt 1561 ggagttcgat gtccttcccg cctatgatgc actaggtcag ctgcggtctg actacacctc 1621 caggctcaaa gcctacaaga agctcattga gctgtatgcc tcacaggaca gcctcaaagg 1681 aggggagttt tcagtctgtt ttacagagct acagagagac ttcattgaaa ccaggcccac 1741 caaactcaag ggtctgatcc gcctgatcaa gcactggtac aaacagtgtg aaaggaagat 1801 gaagccaaaa gcatctttgc ctccaaagta cgcactggag ctgctcaccg tgtatgcgtg 1861 ggagcatggc agtggcacag atggcttcga cactgctgaa ggcttccgga ccgtcctgga 1921 cttggtcata agataccggc agctctgcgt cttctggaca gtcaattaca actttgagga 1981 ggatcacatg aggaagttcc tactgaccca gatccagaaa aagaggcctg tgatcctgga 2041 tccagcagat cccacaggtg atgtgggagg aggtgaccgc tggtgttggc atcttctagc 2101 caaagaagca aaggagtggc tgtcctcctc ctgtttccaa gtggagccaa aaagccccgt 2161 gcagccgtgg aaagtaccag tagtacagac tccaggaagc tgtggagctc agatctaccc 2221 tgtggtgggt ggggtgtact aagagagtgc attcagctct ggagggaaaa tgctggaaga 2281 agcttctaga gacatctggc aaagactctg c // (SEQ ID 35) LOCUS AY250706  4015 bp mRNA linear ROD 06-MAR-2003 DEFINITION Rattus norvegicus 2′-5′ oligoadenylate synthetase 3 mRNA, complete cds. ACCESSION AY250706 /translation = “MDLYHTPAGALDKLVAHSLHPAPEFTAAVRRALGSLDNVLRKNG AGGLQRPRVIRIIKGGAHARGTALRGGTDVELVIFLDCLRSFGDQKTCHTEILGAIQA LLESWGCNPGPGLTFEFSGPKASGILQFRLASVDQENWIDVSLVPAFDALGQLHSEVK PTPNVYSSLLSSHCQAGEHSACFTELRKNFVNIRPVKLKNLILLVKHWYRQVQTQVVR ATLPPSYALELLTIFAWEQGCRKDAFSLAQGLRTVLALIQRNKHLCIFWTENYGFEDP AVGEFLRRQLKRPRPVILDPADPTWDLGNGTAWCWDVLAKEAEYSFNQQCFKEASGAL VQPWEGPGLPCAGILDLGHPIQQGAKHALEDNNGHLAVQPMKESLQPSNPARGLPETA TKISAMPDPTVTETHKSLKKSVHPKTVSETVVNPSSHVWITQSTASSNTPPGHSSMST AGSQMGPDLSQIPSKELDSFIQDHLRPSSQFQQQVRQAIDTILCCLREKCVDKVLRVS KGGSFGRGTDLRGKCDVELVIFYKTLGDFKGQNSHQTEILCDMQAQLQRWCQNPAPGL SLQFIEQKSNALHLQLVPTNLSNRVDLSVLPAFDAVGPLKSGAKPLPETYSSLLSSGC QAGEHAACFAELRRNFINTRPAKLRSLMLLVKHWYRQVAARFEGGETAGAALPPAYAL ELLTVFAWEQGCGEQKFSMAEGLRTVLRLVQQHQSLCIYWTVNYSVQDPAIRAHLLRQ LRKARPLILDPADPTWNMDQGNWKLLAQEAAALESQVCLQSRDGNLVPPWDVMPALLH QTPAQNLDKFICEFLQPDRHFLTQVKRAVDTICSFLKENCFRNSTIKVLKVVKGGSSA KGTALQGRSDADLVVFLSCFRQFSEQGSHRAEIIAEIQAQLEACQQKQRFDVKFEISK RKNPRVLSFTLTSKTLLGQSVDFDVLPAFDALGQLKSGSRPDPRVYTDLIQSYSNAGE FSTCFTELQRDFISSRPTKLKSLIRLVKHWYQQCNKTVKGKGSLPPQHGLELLTVYAW ERGSQNPQFNMAEGFRTVLELIGQYRQLCVYWTINYGAEDETIGDFLKMQLQKPRPVI LDPADPTGNLGHNARWDLLAKEAAAYTSALCCMDKDGNPIKPWPVKAAV” BASE COUNT 887 a 1086 c 1119 g 923 t ORIGIN 1 gaaactctcc tgagggcatg ggtcaacatg gacctgtacc acacgccagc cggagctctg 61 gacaagctgg tggcccacag cctgcaccca gcccctgagt tcacagcggc tgtgcggcgt 121 gctctggggt ccctggacaa cgtcctaagg aagaacggag ccggagggtt acagagacca 181 agggtgataa ggatcatcaa gggaggagcc catgctcgag gcacagctct cagaggtggc 241 actgatgtcg aactcgtcat cttcctcgac tgcctccgga gctttggcga ccagaagacc 301 tgtcacacag agatcctggg cgccatacaa gcattgctgg agtcctgggg gtgcaaccct 361 gggcctggcc tgacttttga gttttctggg ccaaaggcgt ctggcatctt acagtttcgc 421 ctggcatcgg tggaccaaga aaactggata gatgttagcc tggtgcctgc cttcgatgcc 481 ctaggacagc tccactctga agtcaagcca acacccaatg tgtactcctc cctcctcagc 541 agccactgcc aggctgggga acactcagcc tgcttcacag agctccggaa gaactttgtg 601 aatatccgcc cagtcaaact taagaactta atcctgctgg tcaaacactg gtaccgccag 661 gtgcagacac aggttgtgag agccacactg ccccctagct acgcgctgga gctgctcacc 721 atctttgcct gggagcaggg ctgtaggaag gatgccttca gcctggccca agggctccgg 781 actgtcctgg ccttgatcca acgcaacaag catctctgca ttttctggac ggaaaactac 841 ggcttcgaag accctgcagt tggggagttc ttgcgaaggc agcttaagag acccaggccc 901 gtgatcctgg atccagctga cccaacatgg gacttgggca atgggacagc ctggtgctgg 961 gatgtgcttg ccaaggaggc tgaatacagc tttaaccagc agtgcttcaa ggaggcctca 1021 ggagcccttg tgcaaccttg ggaggggccg ggccttccat gtgctgggat cttggatttg 1081 ggtcacccta tccaacaagg agctaagcat gcccttgaag acaacaatgg ccaccttgct 1141 gttcagccaa tgaaagagag cctacaacca tcaaatccag cccgaggact cccagaaaca 1201 gccaccaaga tctccgctat gccagaccca acggtcactg aaacccacaa gagcctcaaa 1261 aaatcagtgc acccaaagac tgtcagtgaa acagtggtga atccctcaag tcatgtttgg 1321 atcacccaga gtacagcatc ctcaaacacg cctccgggcc actctagtat gtccaccgct 1381 gggtcacaga tgggcccaga tctgtcacag atccccagca aggagctgga ctccttcatc 1441 caggaccacc tcaggccgag ttcccagttc cagcagcagg tgaggcaggc catcgacacc 1501 atcctgtgct gcctccggga gaagtgtgta gacaaagtct tgagagtcag caagggtggc 1561 tcttttggcc gtggcacaga cctcaggggc aaatgtgatg tggagcttgt catcttttat 1621 aaaactctcg gggacttcaa gggccagaac tcacaccaga cagagatcct gtgtgacatg 1681 caggcccagc tgcagcgctg gtgtcagaac ccagcacctg gactgagcct ccagtttatt 1741 gaacagaagt ccaatgctct gcatcttcag ctggtgccca ccaacctcag caaccgggta 1801 gacctcagtg tgctgcccgc ttttgatgca gtggggccgc tgaagtccgg cgccaaacct 1861 ctacccgaga cgtactcctc cctcctcagc agcggctgcc aggctgggga gcatgcagcc 1921 tgcttcgcag agctccgaag gaacttcata aacactcgcc ctgccaaact taggagcctg 1981 atgctactgg tcaaacactg gtaccgccag gttgccgctc gatttgaagg aggagagaca 2041 gcaggtgctg ctctgccccc agcctatgcc ctggagctcc tgacagtctt tgcctgggaa 2101 caaggctgcg gagaacaaaa gtttagcatg gctgaaggcc tgcggactgt cctgaggctg 2161 gtccagcagc accagtcact ctgtatctac tggacagtca actacagtgt gcaggaccca 2221 gccatcagag cacaccttct ccgccagctt cggaaagcca ggcctctaat cctagaccct 2281 gcagatccca cctggaacat ggaccagggc aactggaagt tgctggctca ggaggcggct 2341 gccctggagt cacaagtctg ccttcagagt agggatggga atctggtgcc accatgggat 2401 gttatgccag ccctccttca ccagaccccg gctcagaacc tggacaagtt catctgtgaa 2461 ttcctccagc ctgaccgcca tttcctgact caggtgaaga gagcagtgga caccatatgt 2521 tccttcctga aagaaaactg cttccggaat tctaccatca aggtgctcaa ggtggtcaag 2581 ggtgggtctt ctgccaaagg cactgctcta caagggcgct cggatgctga cctggtggtg 2641 ttcctcagct gcttccgcca gttctctgaa caaggcagcc atcgggcaga gatcatcgcg 2701 gagatccagg ctcagctgga ggcgtgtcag cagaagcaga ggttcgatgt caagtttgag 2761 atctccaaga ggaagaaccc ccgagttctc agcttcacgc tgacatccaa gacgctgcta 2821 ggccagagcg tggacttcga tgtgctgcca gccttcgatg ctcttggtca gctgaagtcc 2881 ggctctcggc cagatccccg ggtctacacg gacctcatcc agagctacag taatgcagga 2941 gagttctcta cctgcttcac ggagctgcag cgggacttca ttagctcccg tcccaccaaa 3001 ctcaagagtc tgatccgtct ggtgaaacac tggtaccaac agtgtaacaa gacagtcaag 3061 gggaagggtt ccttgccccc ccagcacggg ctggagctcc tgactgtgta cgcctgggag 3121 cgaggcagcc agaaccccca gttcaacatg gcggagggct tccgcacagt tctggagctg 3181 attggccagt accgtcagct gtgcgtctat tggaccatca actacggtgc agaagacgag 3241 accatcggag acttcctgaa gatgcagctt cagaagccca ggcctgtcat cctggaccca 3301 gctgacccga caggcaacct aggccacaat gcccgctggg acctgcttgc caaggaggct 3361 gcagcataca catctgccct gtgctgcatg gacaaggacg gcaaccccat caagccatgg 3421 ccagtaaagg ccgctgtgtg aagtccagaa agatcaaaaa gtgacaccag ccctcagcaa 3481 gggatactca gaatatctgg ccagatgtgt gtgtgtgtgt gtgtgtgtgt gtgttgtgta 3541 ttgtgtttat ctatatatgt ttctgtgctg tgtctgtgtg tctctgtagg tggtgtgtgt 3601 ctgtgtaccc acaggtgtct acatgtgtct gtatatatgt aagagtgtgt gtatgtatgt 3661 atgttcacgt gtctctgtgt gtgtgcatct gtgtgtttgt atgtagtgtg tctataggtg 3721 tatccttatg agtgtgtgtg tttgtggtgg agtgtgtgtg tgtctgtgta tctgtgggtg 3781 tctatatgtg tctgagtgtg tgtgattatt tgtgtgttta tgtgtctgtg tatttgtgtg 3841 tagtgagttt ataggtgcat ctgtgtgtct atatgtatat gtgtgtctat gtgtgtctat 3901 ggtgtgtgtc cgtgtatctg tgggtgtcta tgtgtgtctg tatgtacgtg tgtgtgtgtg 3961 tgacttgctt tgtccaaatg attgtatgta tgtatgtgtg ctcatgtggc tctgt // (SEQ ID 36) LOCUS AY243505  1682 bp mRNA linear MAM 13-JUN-2003 DEFINITION Bos taurus 2′-5′-oligoadenylate synthetase 1 (OAS1) mRNA, complete cds. ACCESSION AY243505 VERSION AY243505 /translation = “MELRNTPAGSLDKFIEDHLLPDEEFRMQVKEAIDIICTFLKERC FRCAPHRVRVSKVVKGGSSGKGTTLRGRSDADLVVFLTNLTSFQEQLERRGEFIEEIR RQLEACQREETFEVKFEVQKRQWENPRALSFVLRSPKLNQAVEFDVLPAFDALGQLTK GYRPDSRVYVRLIQECKYLKREGEFSPCFTELQRDFLKNRPTKLKSLIRLVKHWYQLC KEQLGKPLPPQYALELLTVYAWEQGCNKTGFITAQGFQTVLKLVLKYQKLCIYWEKNY NSENPIIEEYLTKQLAKPRPVILDPADPTGNVAGKDANSWERLAQAALVWLDYPCFKK WDGSPVGSWDVSPQEHSDLMFQAYDFRQHCRPSPGIQFHGGASPQVEENWTCTIL” BASE COUNT 436 a 431 c 431 g 384 t ORIGIN 1 gcacgagcac agattcaggc agcagctctg ccgcctctgg ctctccagtc cccagcaccg 61 tgatggagct cagaaatacc ccggccgggt ctctagacaa gttcatcgaa gaccacctcc 121 tgccagacga ggagttccgc atgcaggtca aagaagccat cgacatcatc tgcactttcc 181 tgaaggagag gtgtttccga tgtgcccctc acagagttcg ggtgtccaaa gttgtgaagg 241 gcggctcctc aggcaaaggc acgaccctca ggggacgatc agatgctgac ctcgtcgtct 301 tcctcaccaa tctcacaagt tttcaggaac agcttgagcg ccgaggagaa ttcatcgaag 361 aaatcaggag acagctggaa gcctgtcaaa gagaggaaac atttgaagtg aagtttgagg 421 tccagaaacg gcaatgggag aatccccgcg ctctcagctt tgtgctgagg tcccccaagc 481 tcaaccaggc ggtggagttc gatgtcctgc ccgcctttga tgccctaggt cagttgacca 541 aaggttacag acctgactct agagtctatg tccggctcat ccaagagtgc aagtacctga 601 agagagaagg cgagttctcc ccctgcttca cggagctgca gcgagacttc ctgaagaatc 661 gtccaaccaa gctgaagagc ctcatccgcc tggtgaagca ctggtaccaa ctgtgtaagg 721 agcagcttgg aaagccattg cccccacaat atgctctgga gcttctgacg gtctatgcct 781 gggagcaagg atgcaataaa acaggattca tcacagctca gggatttcag actgtcttga 841 aattagtcct aaagtatcag aagctttgca tctactggga aaagaactat aactctgaaa 901 accctattat tgaagaatat ctgacgaagc aacttgcaaa acccaggcct gtgattctgg 961 acccggcgga ccctacagga aatgttgctg gtaaagacgc aaatagctgg gagcggcttg 1021 cacaagcggc tttggtctgg ctggattacc cgtgctttaa gaaatgggat gggtctcccg 1081 tgggctcctg ggatgtgtcg ccccaagaac acagtgacct gatgttccag gcctatgatt 1141 ttagacagca ctgtagaccc tctccaggaa tccagttcca cggaggagcc tctccccagg 1201 tggaagagaa ctggacatgt accatcctct gaatgccaga gtatcttgga ggcaaggtct 1261 ccagagccgt ctgggccagc cctcttcact tctagggata gggggcttgg atccaaagac 1321 agctgtgaat tgatgtcaga cctgggacca gaatccaggt ctcctgaccc ccagccttcc 1381 tgctattctg tgctgtcttt tctttcatag acaatgctcc ccattggagc ctgacaatag 1441 cctctctgag ccaccaggag agactcaggc aaaagagtgg aatcccagcc ttgactttct 1501 tctgtgaacc tgaggggaaa ggtgatggtc caatttattg tcaataataa caaaaatagt 1561 agcaaatgcc atttgttggg tgttaattag cttcaaggta cagcgccaag aagtatacct 1621 gcatattatg tgtgtgtgtg catattcatt gattcaacta aagatattaa ttgggcacct 1681 gc // (SEQ ID 37) LOCUS AY321355  1601 bp mRNA linear MAM 11-JUN-2003 DEFINITION Equus caballus 2′-5′ oligoadenylate synthetase 1A (Oas1a) mRNA, complete cds. ACCESSION AY321355 /translation = “MELQKTPARNLDKFIEDYLLPDTRFRRQVREAIDIICSFLKERC FRGAVPPVRVSKVVKGGSSGKGTTLRGRSDADLVVFLDYLTSFREQFERRAEFIKEIR RQLEACQREKRFDVEFEVQGQQWARPRALSFVLTSPQLNEGVEFDVLPAFDVLGQVTT SYRPDPDIYVLLIKECQSLGKEGEFSPCFTELQRAFLRQRPTKLKSLIRLVKHWYQKC KDKLGKPLPAQYALELLTVYAWEQGSRQTEFNTAQGFRTVLELVLKYQQLCIYWTKYY NFDDPVIGQYLKRQLKKPRPVILDPADPTGNVGGGDPRSWPRLAQEARAWLSYPCFKN WDGSPVGSWDVGPEEDSEDDTLTWAERAYYQCDHGRRPEFPQTGSTPQRASAPDAEEN WTCTIL” polyA_signal 1576 . . . 1581 /gene = “Oas1a” BASE COUNT 372 a 452 c 450 g 327 t ORIGIN 1 agtttctggg agccagtccc acgagcacca gctcctctgt ccccacccgg gcgtcacgat 61 ggagctccaa aagaccccag ccaggaatct ggacaagttc attgaagact atctcttgcc 121 agacacacgg ttccgcaggc aggtccgaga agccatcgac attatctgca gtttcctgaa 181 ggagaggtgt ttccgaggtg ccgttccccc tgtgcgggtg tccaaagtgg tgaagggtgg 241 ctcctcaggc aaaggcacga ccctcagagg ccgatccgat gctgacctcg tcgtcttcct 301 tgactacctc acgagtttcc gggagcagtt tgagcgccga gcagagttca tcaaggagat 361 tcggaggcag ctggaagcct gtcaaagaga gaagaggttt gacgtggagt tcgaggtcca 421 ggggcagcag tgggcgaggc cccgcgcgct cagcttcgtg ctcacgtcgc cccagctcaa 481 tgagggggtg gaatttgatg tcctgcctgc ctttgatgtc ctaggtcagg tgactacatc 541 gtacagacct gaccctgaca tatatgtcct actcatcaaa gaatgccagt ccctggggaa 601 ggagggagag ttctccccct gcttcacgga gctgcagcga gccttcctga ggcagcggcc 661 aaccaagctc aagagcctca tccgcctggt caagcactgg taccaaaagt gcaaggataa 721 acttgggaaa ccactgccag cacagtacgc cctggagctc ctgacagtct atgcttggga 781 acagggaagc agacaaacag aattcaacac agctcaggga tttcggactg tcttggaact 841 agtcctgaag taccagcagc tttgcatcta ctggacaaag tattacaact ttgatgaccc 901 tgttattgga caatacctga aaaggcagct caagaaaccc aggcctgtga ttctggaccc 961 ggctgacccc acaggaaacg ttggtggtgg agacccacgc agctggcctc ggctggcaca 1021 ggaggcgaga gcctggctga gttacccgtg ctttaagaat tgggacgggt ctccagtggg 1081 ctcctgggac gtggggcctg aagaagacag cgaggacgac actttgacct gggctgagcg 1141 cgcatattac cagtgcgacc acggacggcg ccctgaattc ccgcagaccg gcagcacgcc 1201 ccagagggca tccgctcccg acgcggaaga gaactggacc tgcaccatcc tctgatcgcc 1261 ggcgcagcgt ggaggagagg actccagagt cgggggggcc agccccctca tttcctgggc 1321 gggatcttat cggctgtgac ttggcatcag tcctaggacc agaatccggg tctcctgacc 1381 cctcttcctg ctgttcccct ctttctcgcc ctccctaggt agcgctgccc gcagcctcat 1441 cccgccacag cctgttttct gacaatattc tctgagaggc aacagttgag gtttagacaa 1501 aagagtggaa actcagcctt gactttcttc tgtgtgcctg gtgagaaggt tatggtccaa 1561 tttattatca ataacaataa aaataatagc agataaaaaa a

The present invention further provides a method of evaluating yellow fever virus susceptibility in a subject, which comprises obtaining a nucleic acid (e.g., without limitation, DNA, RNA) from the subject, wherein the nucleic acid comprises at least a portion of OAS gene, or a transcription product thereof; and analyzing at least a portion of the nucleic acid, wherein the existence of at least one SNP selected from the group consisting of rs3741981, rs10774671, rs2660, rs11352835, rs15895, and transcription products thereof in the nucleic acid indicates the susceptibility of the subject to yellow fever virus-associated condition. In one embodiment, the OAS gene is OAS1 or OAS2 gene. In another embodiment, at least a portion of the nucleic acid may be analyzed by genotyping, sequencing, or hybridization. In yet another embodiment, the yellow fever virus is a yellow fever virus vaccine and the yellow fever virus-associated condition is a condition associated with yellow fever vaccine-associated viscerotropic disease.

Also provided is a method of evaluating tick-borne encephalitis virus susceptibility in a subject, which comprises obtaining a nucleic acid (e.g., without limitation, DNA, RNA) from the subject, wherein the nucleic acid comprises at least a portion of OAS gene, or a transcription product thereof; and analyzing at least a portion of the nucleic acid, wherein the existence of at least one SNP selected from the group consisting of rs1293762, rs2240193, rs2072136, rs1732778, rs12819210, and transcription products thereof in the nucleic acid indicates the susceptibility of the subject to tick-borne encephalitis virus-associated condition. In one embodiment, the OAS gene may be OAS1, OAS2, OAS3, or OASL gene. In another embodiment, at least a portion of the nucleic acid may be analyzed by genotyping, sequencing, or hybridization. In still another embodiment, the tick-borne encephalitis virus-associated condition may be at least one of fever, meningitis, or a central nervous system disease.

In addition, the present invention provides a method of evaluating flavivirus susceptibility in a subject, comprising obtaining a list of flavivirus susceptibility-related SNPs; obtaining a nucleic acid from the subject; and analyzing at least a portion, of the nucleic acid, wherein the existence of at least one SNP selected from the list in the nucleic acid indicates the susceptibility of the subject to flavivirus-associated condition. A list of flavivirus susceptibility-related SNPs may be obtained or created using methods known in the art, such as, compiling informations from professional publications, conducting genotyping of patients who are susceptible to flaviviruses, and/or combination thereof.

The present invention is described in the following Examples, which are set forth to aid in the understanding of the invention, and should not be construed to limit in any way the scope of the invention as defined in the claims which follow thereafter.

EXAMPLES Example 1

Cell Cultures and Virus Stocks

Cell lines were previously established by SV-40 transformation of embryofibroblasts obtained from congenic C3H.PRI-Flv^(r) and C3H/He (9). Baby hamster kidney (BHK-21/WI2) cells (referred to hereafter as BHK cells) were used for virus plaque assays (8).

The cDNAs corresponding to the ORFs of the C3H.PRI-Flv^(r) alleles of the Oas1b (AF328926) and Na⁺/Ca²⁺-exchanger (AF261233) genes were cloned separately into the pEF6Ny5-His-TOPO mammalian expression vector (Invitrogen) and these plasmids were transfected into susceptible C3H/He cells using LipofectAMiNE 2000 (Life Technologies). Stable integrants were selected using blasticidin S and cells from individual foci were isolated with cloning rings and propagated. Expression of the recombinant proteins, which contained C-terminal 6×His and V5 tags, was analyzed by Western blotting of cell lysates using V5 antibody (Invitrogeen). Stable cell lines expressed a low level (1×), an intermediate level (8×) or a high level (20×) of Oas1b protein were obtained.

A stock of West Nile virus (WNV), strain Eg101, was prepared as a 10% (w/v) newborn mouse brain homogenate (titer=2×10⁸ PFU/ml). A stock of Sindbis virus, strain SAAR 339, was prepared as a 10% (w/v) newborn mouse brain homogenate (titer=7×10⁹ PFU/ml). For virus growth experiments, confluent monolayers in T25 flasks were infected with WNV or Sindbis virus at a multiplicity of infection (MOI) of 0.5. Both viruses were titered on BHK cells by plaque assay.

Example 2

Construction of the BAC Contig

A single genomic clone, 171N24, which contained the D5Mit159 marker and was about 40 kb in length, was isolated from a mouse BAC library (Baylor College of Medicine) using a unique probe derived from D5Mit159. The terminal sequence obtained from the T7 promoter side of the 171N24 clone did not match any of the DNA sequences in the GenBank database, but the sequence located next to the SP6 promoter was part of a large interspersed repeat. Additional BAC clones were subsequently isolated from the RPCI-23 C57BL/6 mouse BAC library (Roswell Park Cancer Institute) using a probe designed from the 171 N24 clone sequence adjacent to the T7 promoter. Four positive signals were detected and the clones, 244P21, 27401, 297M4, and 359J23, were purchased and analyzed. The size of the insertion in each clone was estimated from restriction patterns observed after pulse-field gel electrophoresis. The terminal DNA sequences for each of the BAC clones were determined and used to design eight new primer pairs for PCR amplification of fragments from each end of each BAC clone. Each BAC clone DNA was then tested as a template in a PCR with each primer pair and the data obtained was used to align the clones into a single BAC contig of 300 kb.

Two sequences, 297M4T7 and 244P21SP6, which were the most distal in the initial contig were then used to re-screen the library and eight additional BAC clones were isolated. These clones were partially sequenced and aligned into the contig by screening them with other BAC clone terminal sequences. A GenBank search against the 5′ and 3′ BAC insert sequences identified of one additional BAC clone, 39M18 (AC015535).

Physical Map of the Flv Interval

To create a genomic contig, two independent mouse BAC libraries were screened and fourteen BAC clones were isolated. Alignment of these clones provided a BAC contig with an estimated length of more than 700 kb (FIG. 1). Two flanking microsatellite markers, D5Mit408 and D5Mit242, were mapped outside the contig according to the Celera mouse .database. The D5Mit159 marker was located in the central part of the contig (FIG. 1).

Example 3

Isolation of Transcription Units From the BAC Contig

Direct cDNA selection, exon trapping and searches of genes annotated in the Celera database (www.celera.com), were used to identify transcripts from the Flv interval. Direct cDNA selection was performed according to the protocol of Lovett (17) using adaptor-ligated double-stranded cDNA prepared from C3H.PRI-Flv^(r) cells. Exon trapping was performed using an Exontrap kit (MoBiTec). The cDNAs obtained after each exon trapping or cDNA selection experiment were tested by hybridization with the different BAC clone DNAs, and those that showed specific hybridization with the initial BAC clone DNA were cloned into a pCR-XL-TOPO vector (Invitrogen) and sequenced.

The length of the mRNA corresponding to a partial cDNA isolated by cDNA selection or exon trapping was estimated by Northern blotting using the method of Sambrook et al. (18). The partial cDNA sequences were extended by RACE using a Marathon cDNA amplification kit (Clontech). The expression patterns of the candidate genes were analyzed using mouse multiple tissue poly-A⁺ (Stratagene) and total RNA (Seegene) Northern blots hybridized to probes excised with endonucleases from the cDNAs and labeled with the RTS RadPrime kit (Life Technologies).

Partial and full-length cDNA sequences were used to search the Celera mouse genome database to identify additional transcripts from closely linked genes in the Flv region. Primer pairs designed from sequenced cDNAs and from gene sequences obtained from the Celera database were used to amplify cDNAs from the congenic C3H.PRI-Flv^(r) and C3H/He mouse strains. The primer sequences are listed in Table 5 (published as supporting information).

Transcript Map of the Flv Region

Direct cDNA selection and exon trapping techniques as well as searches of the GenBank and Celera mouse databases were used to identify candidate genes. Four novel transcripts, a Ca²⁺-channel (AF217002), an unknown mRNA (AF217003), an ATP-dependent helicase (AF319547), and a serine dehydratase (AF328927), were identified by direct cDNA selection. Three novel transcripts, a Na⁺/Ca²⁺-exchanger (AF261233), the Oas2 (AF418010), and the Oas3 (AF453830), were detected by exon trapping. The partial sequences obtained were extended to full-length cDNAs by 5′ and 3′ RACE techniques. Two previously identified genes, Oas1a and Oas1b (AF328926), were also cloned using the exon trapping technique (FIG. 1).

Although small (42 kDa), medium (70 kDa), and large (105 kDa) forms of 2′-5′ oligoadenylate synthetases had previously been detected in mice using various biochemical techniques (25-26), only the cDNAs of some of the mouse 42 kDa proteins had been previously cloned (27-29). Three DNA sequences of the Oas1a gene were reported in the Mouse Genome Informatics (MGI) database (www.informaticsjax.org) under the accession ID 97429. Two of these sequences, M33863 and X04958, are almost identical to each other and to the Celera transcript, mCT15312, whereas the third sequence, X58077, is similar to the Celera transcript mCT15074, which maps to a different genomic region. We designated this gene Oas1g (see below). The sequence, AF328926, cloned in this study was identical to the previously isolated partial (576 bp) Oas1b sequence, X55982 (28). Two other sequences, M63849 and M63850, deposited in MGI under the accession ID 97430 and also designated Oas1b were similar to each other, but not to X55982 and AF328926 nor to any mouse transcripts, expressed sequence tags (EST) or genomic sequences in neither the NCBI or the Celera databases. However, M63849 and M63850 showed identity with the human OAS1 sequences and it is likely that these two sequences were cloned from a mouse cDNA library contaminated with human clones.

Twelve additional genes were identified in the Flv region by searching the Celera mouse database with sequences from the nine loci detected by cDNA selection and exon trapping. The LIM homeobox 5 (Lhx5), a threonine dehydratase (BC021950), an unknown protein (AK017032), the RAS protein activator-like 1 (Rasal1), the deltex 1 (Dtx1), the Oas1c (AB067528), the rabphilin 3A (Rph3a), and the protein tyrosine phosphatase, non-receptor type 11 (Ptpn11) sequences were available in GenBank. Genomic and cDNA sequences of four novel genes annotated by the Celera database (subsequently named Oas1d, Oas1e, Oas1f, Oas1g, see Table 1) were also identified in the Flv region and their sequences were used to search the NCBI mouse EST database. The EST sequences obtained were used to generate cDNA consensus sequences, as well as, to design PCR primers for the amplification of each novel gene from mRNA. One additional gene, Oas1h (AB067530), not annotated in Celera, was subsequently identified using a BLAST search of the NCBI database using the Oas1b sequence as a query. The Oas1h cDNA sequence was used to search the Celera database and this gene was mapped on the Flv interval between Oas1f and Oas1g (FIG. 1).

Example 4

Amplification and Sequencing of the Oas1b Exons From Genomic DNA

Genomic DNAs for eight mouse strains, 129/SvJ, BALB/c, BRVR, C57BLJ6, CASA/Rk, CAST/Ei, CBA/J, and MOLD/Rk, were purchased from Jackson laboratory and used for PCR amplification of Oas1b exons. The primers (Table 6, supporting information) used for amplification and direct sequencing were designed from the genomic DNA sequence of the Oas1b gene (AC015535).

Example 5

Phylogenetic and Domain Architecture Analysis of Oas Sequences

Protein sequences of mouse and human 2′-5′ oligoadenylate synthetases 2 and 3 were divided into fragments corresponding to a single functional unit (19). Multiple sequence alignments were constructed using CLUSTAL X (20). Phylogenetic trees were built from multiple alignments using the neighbor-joining method (21). The bootstrapping procedure (22) was applied to the PHYLIP format tree output. Known and putative domains in Oas sequences were revealed by searches against Pfam (23) and ProDom (24) databases. TABLE 4 Mouse 2′-5′ oligoadenylate synthetase genes and their orthologs. Mouse GenBank accession # Celera Orthologous gene (cDNA clone name) transcript sequences Oas1a X04958, M33863 (L3), mCT15312 rat - Z18877, pig - AJ225090, BC013715 marmot —AF082498 OAS1*-NM_002534, NM_016816 Oas1b X55982 (L1), AF328926, mCT15306 rat - AF068268 AB067529, BC012877, OAS1*-NM_002534, AF418004-AF418009 NM_016816 Oas1c AB067528, AF459815 mCT15073 OAS1*-NM_002334, NM_016816 Oas1d AB067532, AY055829 mCT15317 OAS1*-NM_002334, NM_016816 Oas1e AB067531, AY055830, mCT15075 OAS1*-NM_002334, NM_016816 AY055831 Oas1f AF481733 mCT15304 OAS1*-NM_002334, NM_016816 Oas1g X58077 (L2), BC018470 mCT15074 OAS1*-NM_002334, NM_016816 Oas1h AB067530 none OAS1*-NM_002334, NM_016816 Oas2 AB067535, AF418010 mCT15077 OAS2*-NM_002535, NM_016817 Oas3 AB067534, AF453830 mCT15081 OAS3*-NM_006187 Oasl1 AB067533, AY057107 mCT18390 OASL*-NM_003733 Oasl2 AF068835 mCT118383 unknown mCT18449

TABLE 5 Primers used for PCR amplification of murine genes from the Flv interval. Gene Forward Primer (5′ to 3′) Reverse Primer (5′ to 3′) AF217002 AAGGCTGGCGCAGCTGCCGCT AACCCAGCTAGGTGACAGTCTGG AF217003 ACCTGCCCTCGCGATGGCGGC ATCCTCCTGCCTCATCTTCTGAGT AF261233 ACTAGAGCAGCCAGCCCGTGAGCA CTGGCTTACAGAGTGAGTTCCAGG AF319547 TGTTATGTCCCTCAGGTCCTGCTC AAACTCAATGCTGGGTCAGAGGCA AK017032 TTACTGGAGGCTGTGAAATCTAGG TAGGGCGTGGTGGAAGCTGAACA BC021950 CAGACACAATCTACTCCTCTCGCT CATTGTCAAGTGTATCCCACCCCA Dtx1 CTAAGGGATTGAGATCATGTCCCC GTGCTTGACTCAAGTCCTGGGAAA Lhx5 GAAGTCTTGGTTGATCCGTAACGG TGACTTTGGTCCCGAGAAATTGCG Oas1a AGACCCAGGAAGCTCCAGACTTAG GACAGAACCTTCCAACAGGTGGAC Oas1c AAACACTCCTGGCCTCAGGATGG CAGCCCCAGTGCATTGTGATTTAA Oas1d GTCAGCAAACACTCCTGGCCTC GCGTTTTGCTTTAATTTAGTGCTTC Oas1e TCAGGATGGCGAGGGAACTCTTCA AACTGCCATAAACCCGGCCTGCAT Oas1f GTCAGCAAACACTTCCTGGCCATA CAGGTGGAAGTCAAGCTTGAGTTC Oas1g AGACCCAGGAAGCTCCAGACTTAG AGTTCCACGACAGCGTGTGTCACA Oas1h GGCTGCAGTCAGCAAACATTCCTG CGGTCCTCTCTAGGTCAAAGTCTT Oas2 GACCAGCTAGCAACGATGGGAAAC ACTGACCCAGGATCTTCTGTCCCA Oas3 GAAACTCTACTGAGAGTACCGGTC GGGGAGGAAAGGGTTTATTCAGCT Ptpn11 AAGACGGGAGGAACATGACATCGC AGCAGTCTCTCCTTAGCTGAGGAA Rasa11 TGAACCGGCTGACAGCGTGCTTG AAGAGCCTGTGTCCGGCTTCGAG Rph3a AACCTTCCATGTGGAGTAGTCTGG GGACCTGAAGATGCTTAAGGTCAG Sds TTCCTGATTCTGTCTCACGTGGCT TTGATGACCCACCAGGTGTCCAGG

TABLE 6 Primers used for PCR amplification of the Oas1b exons from genomic DNA. Forward Primer Reverse Primer Exon (5′ to 3′) (5′ to 3′) First AATCCTAGACCTGCAAGTCCA GGTTGCAGCCTGGCTTCTGAA GAG AGT Second TGGTGATGGACTCCAGTTCAG ACTAGAAGGGAGGATGAAGGC CAT ATG Third GGCTGAGCTGTTCCACTGAAT CTCTGTACAGATGAAGCGCAC GAA AGT Fourth TGGCTATAGCACAAGAAGGCA TGACATGAAGAGTGTTGGACG TAG ACC Fifth GGTCAGTTGACAGCAGCTCGT AATAAGGAGAGCCAATGGCCT TTC CAA Sixth CTATTACAGACGGAGGTTGCA TGCTACTGTGAACAGACACCA G TGACC

Example 6

Variability in the 2-5′ Oligoadenylate Synthetase (OAS) Gene Cluster is Associated With Severity of Tick-Borne Encephalitis Virus-Induced Disease

Tick-borne encephalitis virus (TBEV), a member of genus Flavivirus, annually causes about 11,000 human cases in Russia and 3,000 cases in Western Europe. To investigate genetic predisposition to severe TBEV-induced disease, a cohort study was performed wherein 75 unimmunized symptomatic Russian patients were divided into three groups: a) fever (27); b) meningitis (27) and c) severe central nervous system (“CNS”) disease (21). Previously a nonsense mutation in the 2′-5′-oligdadenylate synthetase lb gene was associated with susceptibility to flavivirus-induced disease in mice. Forty one single nucleotide polymorphisms (SNPs) within nine candidate human genes, including the OAS gene family, were genotyped using TaqMan Genotyping Assays and RFLP techniques. Association between severity of TBEV-induced disease and particular SNPs in the OAS1/OAS3/OAS2 gene cluster was detected in the study. Although statistically significant differences in minor homozygote frequencies for several SNPs were found between severe and mild (fever and/or meningitis) forms of the disease, the most significant differences were detected for the rs1293762 SNP (OAS2, intron 2; p<0.01; relative risk 2.9). The minor allele homozygotes of this SNP in combination with the major allele homozygotes for four other SNPs, rs2240193 (OAS1), rs2072136 (OAS3), rs1732778 (OAS2) and rs12819210 (OASL), were present in a third of the severe disease patients while completely absent in the mild disease patients (relative risk 4.9). The probability of development of severe TBEV-induced disease for this multigenic genotype is almost 5 times higher than for other multigenic genotypes detected (p<0.00014). The rs1293762 SNP may be closely linked to an unknown mutation(s) that functionally modulates increased susceptibility to TBEV disease in humans.

Example 7

Fatal Multiorgan Failure Due to Yellow Fever Vaccine-Associated Viscerotropic Disease

Since 1937, the live attenuated yellow fever (YF) 17D virus vaccine has protected about 400 million humans from YF, a mosquito-transmitted disease with a case fatality rate of ₂₀%.^(45,46) Since the late 1990s, 36 cases of YF vaccine-associated viscerotropic disease (YEL-AVD), characterized by multiorgan failure, have been recorded worldwide following administration of vaccine manufactured in the United States, France, Brazil, and China (CDC unpublished data).^(47,48) The risk of YEL-AVD is about three per million doses administered, but is highest among people over 60 years old and among people with a history of thymic disease.^(47,49,50) However, nine (25%) of cases were less than 30 years old, and none of these had reported thymic disease. The detection of YEL-AVD coincided with decreased use of pre-travel immunoglobulin to prevent hepatitis A, leading to conjecture that YEL-AVD might have been prevented in the past by the fortuitous co-administration of immunoglobulin containing antibody against YF virus(YFV).⁴⁶ Other factors hypothesized to explain the occurrence of YEL-AVD include genetic host susceptibility and generation of rare in-host virulent vaccine sub-strains.⁵⁴⁻⁵⁷ The inventors of the present invention evaluated a fatal case of YEL-AVD to better understand why this severe adverse event occurs.

A healthy 22-year-old student received tetanus-diphtheria, hepatitis A, and typhoid polysaccharide vaccines for a trip to Bolivia. Eight days later she received YF vaccine. Two days after YF vaccination she noted redness, swelling and pain at the inoculation site, and three days later she presented to an emergency department with ipsilateral tender axillary adenopathy, myalgias, fever, and vomiting. Physical examination revealed a temperature of 103.5 F., pulse 118/minute, respirations 24/minute and blood pressure 92/54. She was alert but appeared mildly ill with an enlarged but soft left axillary lymph node. There was no rash, jaundice, organomegaly or peripheral edema. She had normal cardiac and lung sounds.

Her white blood cell (WBC) count was 11,500 cells per mm with 92.7% neutrophils, hemoglobin and platelet count were normal, aspartate aminotransferase (AST) was 57 U/L, international normalized ratio (INR) was 1.3, and she had 2+proteinuria. Blood cultures were negative. Urine culture grew ≧100,000 cfu/ml mixed flora. Chest radiograph and electrocardiogram were normal.

She was admitted and administered intravenous fluids, analgesics and anti-emetics. She improved, but 24 hours later, developed crampy abdominal pain, loose stools, and recurrent fever. Her WBC dropped to 2000 cells per mm³, hemoglobin to 11.5 g/dL and platelets to 73,000 per mm.⁴⁷ Her AST increased to 181 U/L total bilirubin to 1.8 mg/dL, and INR to 1.4. Renal function was initially preserved.

On transfer to the intensive care unit (ICU) of a quaternary care hospital seven days after YF vaccination, she reported pleuritic chest pain, dyspnea, and worsening abdominal pain. Chest radiograph revealed pleural effusions. Transthoracic echocardiogram showed minimal pericardial effusion but tamponade physiology secondary to the pleural effusions. Pleural fluid cultures were negative. HIV serology was negative. Anuric renal failure ensued requiring hermodialysis but labile blood pressure precluded net fluid removal. A single dose of intravenous immunoglobulin (IVIG) was administered. Glucocorticoids were initiated and administered through the course of treatment. Early on day 9 after vaccination, she developed hypoxemic respiratory failure requiring mechanical ventilation. Chest radiograph showed dense bilateral consolidation. Nitric oxide therapy was initiated. The following day, vasopressors were started for fluid resistant hypotension. High frequency oscillatory ventilation, soon followed by extracorporeal membrane oxygenation, was initiated for refractory hypoxemia. Bedside echocardiogram showed a markedly depressed ejection fraction of 15%. She died eleven days after YF vaccination. Blood cultures drawn immediately prior to death grew group C beta-hemolytic Streptococcus. Pleural fluid samples grew the same species of Streptococcus in addition to Staphylococcus aureus. Autopsy revealed multiorgan failure and diffuse hemorrhage consistent with disseminated intravascular coagulation. On microscopy her lungs showed diffuse alveolar damage with hemorrhage, acute pneumonia, and diffuse foci of gram positive and negative cocci consistent with aspiration. Post-mortem blood cultures grew Staphylococcus aureus. Immunochistochemical staining showed abundant Staphylococcus aureus antigen in lung tissue and scarce YFV antigen in kidney tissue, but no YFV antigen in liver, spleen, heart, or lung.

Remaining -serum and plasma samples were tested for viremia and immunologic response. The consensus sequence of the virus isolate obtained from blood was compared to the Jot used for vaccination, three 17D reference strains, and an isolate from a young woman who died in Spain following 17D vaccination (GenBank Accession numbers: X15062, X03700, U17067 and DQ118157, respectively). Cytokine levels were assessed using the Beadlyte Human Multi-Cytokine Detection System (Cat# 48-011, 46-127, and 46-129, respectively; Upstate USA Inc., VA)⁵⁸ and the patient's levels were compared to levels in previously stored serum from four healthy unvaccinated people. The patient's DNA was amplified from her whole blood and used to analyze the sequences of selected genes that might influence vaccine response [OAS 1 and 2, TLR3, PKL CCR5, RANTES, DC-SIGN and DC-SIGNR].^(59,60)

17D vaccine strain RNA was amplified from plasma and serum samples by RT-PCR. The estimated viral titer was 61,000 plaque-forming units (PFU)/ml on post-vaccination day 5, rising to a peak of 106,500 PFU/ml the following day (healthy vaccinated people rarely .have greater than 100 PFU/ml²). Viremia dropped eight days after vaccination with the development of YF virus-specific neutralizing and IgM antibody. Viral RNA was detected at low levels to the day of death. Levels of several proinflammatory cytokines and chemokines were elevated at sometime during the clinical course, including IFNg, IL-6, RANTES, GM-CSF, IL-1a, IL-3, IL-7 and IP-10.

The consensus sequence of viral RNA obtained 5 days post-vaccination showed 100% nucleotide identity to the utilized vaccine lot. These sequences differed from a reference strain of 17D-204 at nucleotide positions 1431 (A to C, Asn to Thr), 5362 (C to T, silent), 5641 (A to G, silent), 7496 (T to C, silent), 10,243 (A to G, silent) and 10,722 (A to G, 3′non-coding). Identical changes at positions 5641, 10,243 and 10,722, but not the changes at 1431, 5362, and 7496, were detected in viral RNA from a recent fatal case in Spain.⁵² The Spanish isolate also had a unique silent mutation at 6418.

Comparison of the patient's OAS1 gene promoter and exons 1, 3, 4, and 5 sequences with the GenBanic human genome assemblies NT_(—)09775 or NW_(—)925395 revealed no differences. However, the minor allele was detected at four previously identified single nucleotide polymorphisms (SNPs) in the OASI gene: GG-homozygous for SNP rs3741981 in exon 2, resulting in substitution of Gly for Ser at amino acid position 162; GG-homozygous for SNP rs0774671 in intron 5 (splicing acceptor site); GG-homozygous for SNP rs2660 in exon 6, resulting in substitution of Gly for Arg at position 397 in the p48 isoform; and AA-homozygous for the SNP rs11352835 A/− indel in exon 7 that causes a frame shift and premature translation termination of the p44 transcript. The frequency of the SNP rs3741981 G-allele varies from 0.133 in Europeans to 0.767 in Sub-Saharan Africans. The average frequency of the SNP rs10774671 G-allele is 0.4, for the SNP rs2660 G-allele is 0.231 and for the SNP is rs11352835A-allele is 0.36.

No variations in the sequences of the regulatory elements of the OAS2 gene promoter were observed, but there was a single variation within the OAS2 exons: she was AA-homozygous for SNP rs15895, which causes a premature stop-codon in exon 11. The frequency of the minor A-allele varies from 0.00 in African-Americans to 0.38 in Caucasians. In the PKR gene, the patient was homozygous for the minor allele at 1 of 4 SNPs [C-allele of rs12992188 (frequency 0.41)] in the promoter region and for 1 of 5 SNPs in exon 2 [5′ NCR; T-allele of rs2254958 (frequency 0.4)] and was heterozygous at SNPs: rs4648174 (intron 4), rs2307483 (intron 6) and rs2307469 (silent, exon 15). No mutations were detected in either the promoter or exons of the TLR3 gene. She was homozygous wild type for the SNPs analyzed in the CCR5 gene, CCR5 promoter, RANTES promoter, and DC-SIGN gene.⁵⁹ Her DC-SIGNR gene was heterozygous for the number of repeats in exon 4 (6/5).⁶⁰

The consensus viral RNA sequence obtained from the patient's blood was identical to that of vaccine from the same lot, indicating that the predominant strain had not mutated after inoculation. Although some of the sequence differences from a reference vaccine strain were also detected in an isolate from a similar case of YEL-AVD in Spain, two of these nucleotide changes were silent and one was in a non-coding region. These changes seem unlikely to affect virulence, and other people vaccinated with the same lots did not develop YEL-AVD Clonal sequencing of virus from one earlier YEL-AVD case indicated that a vaccine sub-strain had mutated, and mutated virus was isolated from a child with encephalitis following YF vaccination.^(48,61) Since clonal sequencing of the isolate from this patient was not done, the remote possibility remains that a minor sub-strain mutation somehow altered the overall virulence of the vaccination without altering the consensus sequence. However, viral sequences from other YEL-AVD cases have not suggested loss of attenuation, and YEL-AVD has occurred with vaccine from various lots, strain subtypes and manufacturers.^(52,62)

One of 8 Oas1 genes in mice is associated with flavivirus disease susceptibility.⁵⁴ Four minor allele variations were detected in the patient's OAS1 gene. Three of these were in coding regions, while the other was in an intron splicing site. At least five different OAS1 isoforms are generated by alternative splicing. The p42, p44 and p48 isoforms are most common. The A-allele in DM1 intron 5 SNP rs10774671 produces p52, while the G-allele produces p46. Since the patient was OG-homozygous, she would have produced p46. Computer modeling suggests that p46 may have impaired enzymatic activity.⁶⁴ The patient was homozygous for the G-allele of SNP rs3741981 in exon 2 that causes an amino acid substitution in all of the OAS1 isoforms. The G-allele of this SNP was previously reported to be associated with severe acute respiratory syndrome (SARS) in Asian populations.^(65,66) Homozygosity for the G-allele of SNP rs2660 in exon 6 may alter p48 pro-apoptotic activity. Homozygosity for the A-insertion (rs11352835) in exon 7 produces a frame shift and premature translation termination of p44. Although not currently supported by direct experimental data, the 4 minor alleles in the OAS1 gene and the AA-homozygosity in OAS2 SNP rs15895 leading to truncation of the OAS2 protein could have had an adverse effect on possible OAS-mediated anti-flaviviral activities that contributed to the abnormally high virus levels. Mutations in other candidate genes that were not evaluated might also have influenced the response to YF vaccination.

This patient's viremia peaked on post-vaccination day at 1000 times higher than expected with a subsequent normal antibody response and virus clearance.⁴⁶ By that time, multiorgan failure had developed, likely mediated by inflammatory cytokines. One dose of IVIG was given on post-vaccination day 8 without obvious clinical benefit. Further doses were withheld because of volume overload concerns and the general consensus that she had developed her own protective antibody response. IVIG has been proposed for postexposure prophylaxis against wild-type YF, but has no proven benefit after onset of illness.⁴⁶

The absence of signs of any bacterial infection and the high likelihood that the patient's illness was due to 17D virus infection precluded the early use of prophylactic antibiotics, but in retrospect prophylactic antibiotics might have prevented secondary bacterial sepsis. The pleural effusions, initially sterile, appeared rapidly and were thought to be secondary to renal failure and volume overload. Multiple large venous cannulations may have predisposed to infection and such procedures along may justify prophylactic antibiotic administration in future eases.

While the foregoing invention has been described in some detail for purposes of clarity and understanding, it will be appreciated by one skilled in the art, from a reading of the disclosure, that various changes in form and detail can be made without departing from the true scope of the invention in the appended claims.

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1. A method of evaluating yellow fever virus susceptibility in a subject, comprising: obtaining a nucleic acid from the subject, wherein the nucleic acid comprises at least a portion of OAS gene, or a transcription product thereof; and analyzing at least a portion of the nucleic acid, wherein the existence of at least one SNP selected from the group consisting of rs3741981, rs10774671, rs2660, rs11352835, rs15895, and transcription products thereof in the nucleic acid indicates the susceptibility of the subject to yellow fever virus-associated condition.
 2. The method of claim 1, wherein the nucleic acid is DNA.
 3. The method of claim 1, wherein the OAS gene is OAS1 or OAS2 gene.
 4. The method of claim 1, wherein at least a portion of the nucleic acid is analyzed by genotyping, sequencing, or hybridization.
 5. The method of claim 1, wherein the yellow fever virus is a yellow fever virus vaccine.
 6. The method of claim 1, wherein the yellow fever virus-associated condition is a condition associated with yellow fever vaccine-associated viscerotropic disease.
 7. A method of evaluating tick-borne encephalitis virus susceptibility in a subject, comprising: obtaining a nucleic acid from the subject, wherein the nucleic acid comprises at least a portion of OAS gene, or a transcription product thereof; and analyzing at least a portion of the nucleic acid, wherein the existence of at least one SNP selected from the group consisting of rs1293762, rs2240193; rs2072136, rs1732778, rs12819210, and transcription products thereof in the nucleic acid indicates the susceptibility of the subject to tick-borne encephalitis virus-associated condition.
 8. The method of claim 7, wherein the nucleic acid is DNA.
 9. The method of claim 7, wherein the OAS gene is OAS1, OAS2, OAS3, or OASL gene.
 10. The method of claim 7, wherein at least a portion of the nucleic acid is analyzed by genotyping, sequencing, or hybridization.
 11. The method of claim 7, wherein the tick-borne encephalitis virus-associated condition is at least one of fever, meningitis, or a central nervous system disease.
 12. A method of evaluating flavivirus susceptibility in a subject, comprising: obtaining a list of flavivirus susceptibility-related SNPs; obtaining a nucleic acid from the subject; and analyzing at least a portion of the nucleic acid, wherein the existence of at least one SNP selected from the list in the nucleic acid indicates the susceptibility of the subject to flavivirus-associated condition. 